DE1232190B - Image signal generator tubes with scanning by slow electrons - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

Number: File number: Registration date: Display day:

HOIj

H04n

German class: 21 al -32/35

N 25973 VIII a / 21 al
December 15, 1964
January 12, 1967

Image signal generator tube with scanning through
slow electrons

Applicant:

NV Philips' Gloeilampenfabrieken,
Eindhoven (Netherlands)

Representative:

Dr. P. Roßbach, patent attorney,
Hamburg 1, Mönckebergstr. 7th

Named as inventor:

Roger Auguste Petit,

Palaiseau, Seine-et-Oise (France)

Claimed priority:

France of December 16, 1963 (957295) -

The invention relates to cathode ray tubes for image decomposition, in which a slow Electron beam scans a flat surface or storage electrode that is perpendicular to the axis of the electron gun, the generated signal being taken from this electrode (e.g. a tube with a photoconductive layer or with a mosaic of photosensitive Corpuscles).

Due to the low speed of the electrons, a scanning beam is required that is perpendicular meets the storage electrode. To achieve such a result, one would have to collimate the Carry out the bundle with the help of a rotating lens, the focal point in the deflection center of the bundle lies. Unfortunately, you have an electrostatic deflection system, the advantages of which are known and that in particular, scans with small deflection power and high speed are allowed, with two separate To do deflection centers of the bundle that correspond to the two plate systems.

In the known image signal generator tubes with slow electrons of the orthicon, vidicon type

and the like, it was preferred to

escape to use an electromagnetic

To take deflection system, with the bundle the 2

lines of force flux of the uniform magnetic field that extend parallel to the tube axis. These In this way, however, the anamorphic lens tubes prepare the same difficulty system that in just one like the usual magnetic systems, ie the convergence of the bundle, they bean affects ₃₀ direction, with the result that the two Ablenkspruchen much space, The tube and the feeding device Centers of the bundle that belong to the two pairs of plates are heavy, the energy consumption is considerable and correspond to two virtual deflection centers, the scanning speed is comparatively low. The invention aims at the focal point of the collimation lens to eliminate the aforementioned characteristic properties (shape, potential disadvantages and in particular the possibility, relative arrangement) of the various elements to be able to merge an image signal generator tube with little so that the collimated bundle

meets the storage electrode at a right angle.

The invention has various embodiments that emerge from the description below emerge and in which, among other things, the anamorphic lens system from a channel-shaped There is an electrode that is provided with an opening and at the front of a flat one, for electrons permeable electrode is attached to the

while the deflection system is electrostatic, in a known manner at the exit of the deflection system of the collimating lens an anamorphic lens is centered opposite the tube axis, the system being connected, which consists of at least one additional electrode placed at the exit of the
mentioned deflection system is arranged and their

Shape, dimensions and potential are chosen so that 50 th tube axis is, these two electrodes the virtual center of deflection of the bundle in which are electrically isolated from one another and which Focal point of the mentioned collimation lens lies. trough-shaped electrode has a higher potential.

609 757/265

like to produce weight and consumption, which is particularly important for the tubes that z. B. for use intended on board spacecraft.

The image signal generator tube according to the invention, which is provided with an electrostatic collimating lens in FIG Is provided in the form of a body of revolution with respect to the tube axis, is characterized in that,

The channel-shaped electrode faces the collimation lens and is centered with respect to the tube axis, while its longitudinal axis is perpendicular to the mentioned

For a better understanding, the invention is explained in more detail below with reference to the drawings, in which

F i g. 1 shows, in perspective, a scanning tube according to the invention with parts broken away,

FIG. 2 shows a vertical section through the tube according to FIG. 1 represents

F i g. 3 shows a horizontal section through the same tube and

Fig. 4a, 4b and 4c variants of the anamorphic Show lens system.

F i g. 1 shows the various elements that make up a conventional scanning tube with a longitudinal axis AA ' , namely: the electron beam generator 1, acceleration electrodes 2 with central openings, the shape and dimensions of which can be selected so that corrections of any astigmatism are carried out; an electrostatic deflection system, which consists of two pairs of plates, namely, a pair of plates 3 for the vertical deflection and a pair of plates 4 for the horizontal deflection, which are separated from each other by an electrode 2 b; an electrostatic collimation lens 5 consisting of a series of (e.g. four) cylindrical metal rings of the same diameter as the tube, centered on the axis AA ' and between the baffles 3, 4 and the storage electrode 6 (a photoconductive layer or a mosaic of photosensitive bodies) are arranged.

The acceleration electrodes 2, excluding the electrode 2a, and the baffles 3, 4 are attached to the inner wall of a metal cylinder 7, the diameter of which is equal to that of the tube and which forms a closed space. This space is closed off at both ends by the electrodes 2, 2c. In this way, the whole consisting of the cylinder and the acceleration electrodes has the same potential, which is also the mean potential of the deflection plates. The electrode 2a has a slightly different potential in order to enable corrections of the astigmatism. An anamorphic lens system 8 is attached to the electrode 2c, which closes the space mentioned, on the side of the focusing lens. This system consists of a channel-shaped electrode 8, which is provided in the longitudinal direction with two flat parts 8 b and 8 c, by means of which it can be attached to the electrode 2 c so that it is centered with respect to the tube axis AA ', the The longitudinal axis of the channel is perpendicular to this axis AA ' .

The channel electrode 8 ″ can have a rectangular, cylindrical or polygonal cross section (these shapes are shown in Figures 4a, 4b and 4c, respectively).

The anamorphic lens system 8 is electrically insulated from the electrode 2c by a thin mica layer 9 (with a thickness of, for example, 0.5mm) which is attached between the flat parts Sb and 8c and the electrode 2c. In this way, the anamorphic lens system can have a potential which is considerably higher than that of the electrode 2c.

In this case, the electric field within the trough electrode is created by cylindrical equipotential surfaces determined whose radius of curvature decrease with tension and which in cross-section and in longitudinal section at 11 and 12 in the F i g. 2 and 3 are shown.

In the opening of the electrode 2c, which contains the above-mentioned "electrode permeable to electrons" forms, a grid 10 is stretched out with the same potential, the "bulge" of the equipotential surfaces (which penetrate into the opening) should be avoided, as these "bulges" disadvantageous converging Could bring about effects.

The channel electrode 8 a has a rectangular central window 8 d which is so long that the equipotential surfaces can maintain a cylindrical shape.

This system gives the collimating lens such an astigmatism that it can compensate for the error caused by the non-coincidence of the deflection centers D ₁ and D _{2 of} the two plate pairs 3, 4.

In the F i g. 2 and 3, the solid lines up to electrode 2c are the paths of the bundles, regardless of whether an anamorphic lens system is present or not. This system changes the direction of the beams and the dashed lines are the extension of the distances of the solid lines behind this system towards the electron guns. Viewed from the collimating lens, the bundle in FIG. 2 apparently from D ₁ ', in FIG. 3 of D ₂ '. In reality, the bundle comes in FIG. 2 of D ₁ , in FIG. 3 of D ₂ . Without the use of the anamorphic system, the paths of the bundles would be straight lines up to the collimating lens 5, from D ₁ in FIG. 2 and from D ₂ in FIG. 3. The anamorphic lens system has the effect that each of the deflection centers D ₁ and D ₂ corresponds to a virtual deflection center D ₁ 'or D ₂ ', namely D ₁ ' for the vertical deflection plates, which is shifted forwards _{with respect to D 1 (} Lens effect), and D ₂ 'for the horizontal baffles which _{is shifted backwards with respect to D 2} (effect of a plate with surfaces parallel to each other).

Suitable arrangements of the deflection plates 3, 4 and the cylinder rings forming the collimation lens 5 in relation to one another and a suitable choice of the potentials make it possible to achieve that the virtual deflection centers D ₁ and D ₂ 'merge at the focal point of the collimation lens, so that the collimated The bundle hits the storage electrode at a right angle.

The dimensions and potentials that characterize a practical embodiment of a Tubes according to the invention are given below for further explanation.

The potentials for the selected electrode shapes are determined with the help of the electrolytic trough been:

Diameter of the tube 50 mm

Length of the tube 250 mm

Characteristic properties of the deflection system:

Distance between the two
Pairs of plates, measured from the fastening points 30 mm

Distance between the attachment
of the plates 4 and the electrode 2c 45 mm

Potential 1000 volts

Claims (1)

5 6 Distinguishing features of the collimation lens: A slight astigmatism caused by the anamorphic Distance between the first photic lens system can be caused, and Collimation ring Sa and the ^eme possibly occurring geometric or ElectrodelcdesA deflection system 10 mm other aberration can be done in a manner known per se .,,. _t ,, ·, - 5 with the help of further correction electronics Distance between the cylinder _{electrodes or a modification of the one} described see rings 2 mm correction electrodes are fixed. Height and potential of the successive Rj _n " _e: Claims: Ring 5 a 20 mm; 1500 volts io 1. image signal generator tube with scanning Ring Sb 20 mm; 200 volts slow electrons with an electrostatic e _r m mm · "nn VnIt collimation lens in the form of a body of revolution _in ". _cnv1t pers with respect to the pipe axis, this ^1Omm > ^{50 volt} lens between the two pairs of plates The fast electron (1500-2000 volts) ER ¹ S standing electrostatic Elektronenablenk- drive a delay in the collimating lens, so the system and the perpendicular to the axis of the that a bundle results, the plate to be scanned standing with an energy of electron gun 50 electron volts emerges. The focal point of the colli- sion is attached, characterized mation lens is at a distance of 122 mm in front of the that the collimation lens (5) an anamorphic Storage electrode. ^ao cal lens system (8) is added, which consists of min- Characteristic properties of the anamorphic at least one additional electrode (Sa) consists, see system: those at the exit of the aforementioned deflection system _{T. f 1} "(2) is attached and its shape, dimensions " ^E iU mm gen and potential are chosen so that the vir- Length ⁴⁰ ™ 25 tual deflection center of the bundle in focus Height at the electrode 2 c is 20 mm of the aforementioned collimation lens. Opening 2. image signal generator tube according to claim 1, Height 14 mm, characterized in that the anamorphic Channel-shaped lg _{n "e} ^ ^{e sc} 20 mm lens system (8) consists of a « _Ff °" .. ", '"' 7 "ni '3o electrode (8 a) with an opening (8 d) Opening opposite the elec- ^{trocle 2 c} square _{troneQ permeable flat} electrode (2 c) with beiten is fixed _{> the one at the exit of the} deflection system (2) from Il mm _{in a manner known per se} compared to the Röh- The potential of this anamorphic Luisen axis is centered with the channel electrode systems depends on the geometric shape of the facing and opposite of the collimating lens Channel electrode from: the tube axis is centered and the longitudinal axis Electrode with a rectangular transverse to the channel electrode perpendicular to the mentioned cut (Fig. 4a) 1500 volt tube axis, while the two mentioned Electrode with a semicircular ⁴ ° ^Ε1 ^ ^Γ . ° 1 ^6η are electrically isolated from one another Cross-section (Fig 4 b) 1400 volts ^{and the} roller electrode has the higher potential. τ- _{,,, · 4} · ιι · 'Α "3rd image signal generator tube according to spoke 2, Electrode with a polygonal transverse _{characterized ge} ^ö _{Flag with} i _{netj that the mitt} f _{ere öff!} section (Fig. 4c) 1400VoIt _{voltage de} r channel electrode (8d) is rectangular and Due to the anamorphic lens system, it is much longer than it is high. The improvement created makes it possible to use the 4. image signal generator tube according to one of the wrote collimation lens a storage electrode Proverbs 1, 2 and 3, characterized in that with a large diameter (40 mm) to be scanned under in the central opening of the electrode (2 c) on Retention of the advantages of a completely electrostatic output of the deflection system (2) a fine mesh see scanning system: low energy consumption, 50 grid (10) is stretched. light weight of the tube and the power supply, 5th image signal generator tube after one of the reducers Volume and in particular scanning proverbs 2, 3 and 4, characterized in that genes with high impedance, which can easily be realized with the cross-section of the channel electrode (Sa) right and are adjustable and the scanning speed is high. allow opportunities. 55 6. Image signal generator tube according to one of the The invention is by no means limited to the above Proverbs 2, 3 and 4, characterized in that Embodiment described limited, and the cross section of the channel electrode (8 a) half can then also modifications, especially circular. with regard to the relative dimensioning of the potentials 7. image signal generator tube according to one of the other different elements and the form of the 60 Proverbs 2, 3 and 4, characterized in that anamorphic lens system, the cross section of the channel electrode (8 a) much without to step out of the scope of the invention. is angular. 1 sheet of drawings 609 757/265 1.67 © Bundesdruckerei Berlin