DE2142436C2 - TV camera tube and method of operation - Google Patents

Description

The invention relates to a television camera tube according to the preamble of claim 1.

The potential image determined by the potential distribution in such a tube arises from the fact that the photoconductive layer can be considered to be composed of a plurality of picture elements can. Each picture element can be viewed as a capacitor with a current source in parallel switched whose current intensity is almost proportional to the light intensity on the picture element and the Capacitor discharges The charge of each capacitor increases linearly with the constant light intensity Time off. As a result of the scan, the electron beam passes each picture element periodically and then charges the Capacitor. This makes the voltage of the scanned surface of each picture element periodic reduced to the voltage of the cathode, which is approximately at ground potential The amount of charge, The periodic time required to charge a capacitor is the light intensity on that in question Picture element proportional. The associated current flows through the signal plate, all of the picture elements is common, through a signal resistor, whereby a voltage across the signal resistor occurs, which represents the light intensity of the optical image as a function of the position as a function of time. One like that working television camera tube is generally referred to as a "vidikon" tube.

It is important that such a television camera tube is as short as possible, especially for portable television cameras and for color television cameras containing multiple camera tubes, it is necessary to that a television camera tube with as short a length as possible is used. In the essay “One experimental small color television camera "in" Philips' Technische Rundschau ", 29 (1968), 334-344 is one Television camera tube of the type mentioned above. In this television camera tube, the Electron beam emitted by an electron gun having a cathode, a grid and a Anode is generated by the electric field between these electrodes in a so-called Beam node (cross-over) focused approximately at the point of the anode. The openings in the grille and in the Anode are simple cylindrical openings and the anode forms a whole with the first electrode of the Focusing lens and is at a voltage of 300 V.

The aforementioned beam node is imaged on the photoconductive layer by the focusing lens. The focusing lens is a three-electrode lens of which the first electrode and the last electrode have the same potential while the middle electrode has a different potential The three electrodes of the focusing lens are essentially cylindrical in shape and all three have a relatively great length, what on the electron-optical properties of a lens

Although the aforementioned television camera tube is due to this shape and the potentials used has relatively small dimensions, it has proven necessary to have such Shorten the tube even further.

From US-PS Re 24 673 a cathode ray tube with a focusing lens with three electrodes is known, in which the inside of the second electrode facing the electron beam essentially has one Has a constant cross section and in which the inner surfaces of the first and the third electrode widen in a funnel shape in the direction of the second electrode. The anode forms part of the first electrode and is formed by an elongated piece of pipe. Further focusing lenses ι s this type with funnel-shaped first and third electrodes are from US-PS 29 19 378 and US-PS 27 32 511 known

The invention is therefore based on the object of providing a television camera tube according to the preamble of Form claim 1 so that its length is as short as possible

This object is achieved according to the invention by what is stated in the characterizing part of claim 1 Features solved

Further refinements of the invention are characterized in the subclaims

Calculations of electron trajectories in many examined electrode configurations of the focusing lens a television camera tube according to the invention have demonstrated that a focusing lens of the above-mentioned type can be constructed with a very short length. Furthermore, as a result of the in Cross-sections of the first and third electrodes that widen towards the second electrode Field strength along the axis of the focusing lens at the point of the narrowest cross-sections of these electrodes are influenced in such a way that diaphragms attached there have an extremely low focusing or defocusing effect exert on the electron beam and thus induce almost no aberrations. It should it can be noticed that the focal length belonging to a diaphragm is the difference between the axial Field strengths on both sides of the diaphragm is inversely proportional to achieve that the diaphragm has no Exerts focusing or defocusing effect, the focal length must be infinite. This can be done by approximately achieved that either the field strengths on both sides of the diaphragm are both almost the same Be made zero, or that the aperture, as is the case in the known television camera mentioned, in its elongated cylindrical electrode, or that the difference between them Field strengths by using the electrode configuration of the television camera tube according to the invention is made almost equal to zero.

The embodiment according to claim 2 enables the field strength to be influenced very precisely second electrode facing side dt.r opening, whereby aberrations are reduced to an even greater extent.

The configuration according to claim 3 gives a structurally easily achievable shape of the opening which enables the desired field configuration.

By making an opening according to claim 4, which has a much larger narrowest cross-section than the mentioned aperture in the first electrode, it is achieved that marginal rays, have aberrations that may be caused by the electrons in question in a started a relatively large distance from the center of the cathode with such a direction, that they could still pass through the narrow anode opening and not reach the light-sensitive layer can.

The operating method according to claim 7 is based on the knowledge that the magnification M of an electron optical lens is given by the formula:

where b is the image distance, ν the object distance, Vj the potential at the first electrode and V ₂ the potential at the last electrode. In order to achieve satisfactory sharpness, M must be fixed and be about 1.5 to 2. The image distance and the object distance determine the length of the television camera tube to a considerable extent and must therefore be as small as possible. The image distance is determined to a considerable extent by the length required by the deflection of the electron beam required for scanning. In order to make the object distance as small as possible, the ratio V \ l V _{2 must} therefore be as small as possible.

An embodiment of the invention is explained in more detail below with reference to the drawing. It shows

F i g. 1 shows a television camera tube according to the embodiment of the invention, and

F i g. 2 schematically shows the electrode configuration of the focusing lens of the tube according to FIG. 1.

The in F i g. 1 shown camera tube is of the "Plumbikon" type and contains a glass envelope 1 with a face plate 2, arranged on one side, on which a layer 3 is applied, which consists of a photoconductive Layer exists while a conductive clear signal plate between the photoconductive layer and the faceplate 2 is attached. The photoconductive layer consists essentially of specially activated Lead monoxide and the signal plate made of conductive tin dioxide. On the other side of the envelope 1 are the connecting pins 4 of the tube. Centered along an axis 5, the camera tube contains a Electron gun 6 and a focusing lens 7. Furthermore, the tube contains a grid-shaped Electrode 8 so that the electrons hit the layer 3 perpendicularly. The envelope 1 is of one set surrounded by deflection coils 9, which are only shown schematically and from the electron gun 6 deflect the electron beam generated in two mutually perpendicular directions. That Electron gun 6 includes a cathode 10, a grid 11 and an anode 12. The focusing lens 7 includes a first electrode 13, a second electrode 14 and a third electrode 15. The third electrode 15 is connected via a connecting line 16 connected to a conductive layer 17 on part of the inside of the envelope 1. The attachment points of the mentioned items and their connections with the connecting pins 4 are in the Figure not shown for the sake of clarity.

Ir F i g. FIG. 2 shows the electrode configuration of the focusing lens which is located in the tube of FIG. 1 is used and in this FIG. 1 to 7 is designated. Since the focusing lens is rotationally symmetrical, only that is part of the lying on one side of the axis of symmetry

Configuration shown that includes focusing lens a first electrode 13, of which the anode 12 (see also FIG. 1) forms a part, a second electrode 14 and a third electrode 15. The first electrode 13 is provided with an opening which has two cylindrical parts 18 and 19 contains. The opening 18 has a diameter of 0.020 mm and a length (along the Axis 5) from 0.015 mm. The opening 19 has a diameter of 0300 mm and a length (along the Axis 5) from 0.200 mm. The inner diameter of the cylindrical second electrode 14 is the same as the largest inner diameter of the first electrode 13 and the third electrode 15, 10.5 mm. The lengths of the Electrodes (measured along axis 5) are:

first electrode 13:
second electrode 14:
third electrode 15:

4.5 mm,

10.0 mm,

4.5 mm.

The third electrode 15 is provided with an opening which contains two cylindrical parts 20 and 21. The opening 20 has a diameter of 2.0 mm and a length (along the axis 5) of 0.200 mm. The opening 21 has a diameter of 0.750 mm. The voltages across the electrodes in relation to the Cathode (10 in Fig. 1) are:

at the first electrode 13:
at the second electrode 14:
at the third electrode 15:

50 V,

25 V,

500 V.

In the figure are some equipotential lines with 22.23, 24, 25, 26, 27, 28 and 29; the corresponding Voltages are: 30, 35. 40, 50, 100, 250, 400 and 480 V. With 30, 31, 32, 33, 34 and 35 are some Denotes electron trajectories which all start in the center of the opening 18 from the axis 5. the Electron path 30 extends along axis 5 of the focusing lens. The investigations from which F i g. 2 have shown that electrons which start at a not too large angle to the axis 5, in a point on the axis 5 at the intended distance beyond the opening 21. In the figure

this z. B. shown for tracks 31 and 32 and their continuations. Electrons under one start to large angles to the axis, as z. B. shown for the tracks 34 and 35, however, follow Orbits showing aberrations. From the figure it is clear that such paths on the photoconductive layer would form too large an impact spot, by suitable choice of the diameter the opening 21 does not reach the photoconductive layer. The investigations have also shown that the field strength on the side of the opening 21 facing the second electrode is due to the influence the opening 20 is extremely low. The field strength on the other side of the opening 21 is almost equal to zero because there is an equipotential space due to the conductive layer 17 (Fig. 1). It turns out that the opening 21 can be represented by a thin lens with a focal length of 120 mm, which value in relation to the dimensions of the focusing lens is particularly large as a result of these large ones Focal length, the opening 21 has almost no lens effect, so that it has almost no aberrations The opening 19 is dimensioned in such a way that the field strengths on both sides of the opening 18 are nearly are equal to each other. As a result, the influence of the opening 18 is also expressed as a very great one Focal length, as a result of which the opening 18 also has virtually no focal length Causes aberrations. Due to the large ratio between the voltages at the first electrode 13 and at the third electrode 15 namely 500/50 = 10, and by the configuration of the electrodes according to FIG. 2 is the total length of the television camera tube in relation to the known miniature version with a single focusing lens is considerably reduced already mentioned formula

ν IK ₂

In the known tube the distance between the cathode and the photoconductive layer is 78 mm and in of the tube according to the embodiment of the invention 56 mm (28% shorter).

For this purpose 2 sheets of drawings

Claims (7)

Patent claims: 1. TV camera tube in which are arranged centered along an axis: An electron gun (6) with a cathode (10) and an anode (12) provided with an opening for Generating an electron beam and a focusing lens (7) for focusing the electron beam on a photoconductive layer, which is attached to a signal plate and on one Potential distribution is obtained by projecting an optical image thereon, the Signal plates when the photoconductive layer is scanned by the electron beam, electrical signals provides which correspond to the optical image in which the focusing lens has a first electrode (13), a contains second Ekktrode (14) and a third electrode (15), in which the second electrode (14) located between the first electrode (13) and the third electrode (IS), at which the anode (12) through a flat part of the first electrode (13) provided with a diaphragm opening (18, 19) is formed and the inner surface of the second electrode (14) facing the electron beam is substantially one having constant cross-section, thereby characterized in that the cross section of the first electrode (13) is seen in the beam direction behind the anode (12) expands in a funnel shape and the cross section of the third electrode (15) extends in Seen in the direction of the beam, it is reduced in a funnel-shaped manner 2. TV camera tube according to claim 1, characterized in that the aperture (18,19) in the anode (12) on the side facing the second electrode (14) has a larger diameter than at the point of the narrowest cross section of the aperture (18,19) 3. TV camera tube according to claim 2, characterized in that the aperture (18, 19) in the anode (12) has an almost circular cylindrical part at the point of its narrowest cross section and one contains almost circular cylindrical part on the side facing the second electrode (14) 4. TV camera tube according to one of claims 1 to 3, characterized in that the on of the end of the funnel-shaped third electrode (15) facing away from the second electrode (14) Opening (20, 21) is so small that it restricts the electron beam in its cross section 5. TV camera tube according to claim 4, characterized in that the opening (20, 21) in the third electrode (15) on the side facing the second electrode (14) has a larger diameter than at the point of the narrowest cross section of the opening (20,21) 6. TV camera tube according to claim 5, characterized in that the opening (20, 21) in the third electrode (15) an almost circular cylindrical part at the point of its narrowest cross-section and a nearly circular cylindrical part on the side facing the second electrode (14) 7. A method for operating the television camera tube according to any one of claims 1 to 6, characterized characterized in that at the third electrode a voltage at least four times greater than that at the first electrode