FR2647264A1 - Electron tube with beam indexation and dichroic filter - Google Patents

Abstract

The invention relates to electron tubes, and most especially to display tubes with beam indexation. The screen carries on its upper surface strips of luminophores 16 of alternate colours. Here and there are inserted strips of indexation luminophores 20 which emit at a non-visible wavelength and which produce a luminous signal (detected by a detector 22) when the electron beam strikes them. According to the invention, the screen 14 of the tube includes on its rear face a dichroic filter essentially transparent to the visible wavelengths emitted by the image-forming luminophores 16 and essentially reflecting the wavelength emitted by the indexation luminophores (ultraviolet). The light from the image therefore passes to the observer whilst the light from the indexation signals is trapped in the glass plate 14 and can be collected by a detector 22 placed against the edge of the plate. The proportions of the tube are thus reduced while optimising the resolution of the image, thus making it possible to produce very small tubes (colour television camera view finders).

Description

ELECTRONIC TUBE WITH INDEXING OF
DICHROIC FILTER HARNESS
The invention relates to the manufacture of so-called beam indexing electron tube screens. Color image viewing tubes are particularly affected.

An electronic display tube includes a display screen on which phosphors (in English "phosphors") are deposited, which have the property of emitting light when struck by an electron beam, the light intensity being all the more important that the intensity of the beam is important. The emission color of the phosphor depends on the material from which it is made. In general, triads of phosphors are used, comprising a red phosphor, a green and a blue. An electron gun emits an electron beam which scans the surface of the screen and which is modulated in intensity by a video signal so that each point of
The screen lights up with a desired intensity.

 The screen is subdivided into image points which are defined by zones of phosphors placed at these points. These areas of imaging phosphors can be distributed in several ways. In beam-indexing tubes, the elementary zones are normally parallel strips of phosphors each extending over the entire height of the screen perpendicular to the scanning lines of the electron beam. The phosphor strips are separated from each other by opaque areas. This is what makes it possible to differentiate colors and maintain their purity when luminophores emitting in different colors are juxtaposed on the screen.

 Beam indexing tubes are tubes in which the electron beam passes during its scanning over indexing bands which are bands of phosphors which do not participate in the formation of the image; these phosphors only emit light (generally in ultraviolet) towards a detector which thus locates the passage of the beam at well determined points so that one can know at any time where the beam is and consequently define the video signal to apply. The beam indexing tubes are used in particular for producing a color display with a single electron gun.

 Figure 1 shows the simplest construction of a beam indexing viewing tube. We recognize the envelope 10 of the tube, the electron gun 12, the display screen 14 which is a flat glass plate covered with a layer of phosphors 16 (bands of phosphors of alternating colors separated by opaque bands 17 ). The layer of phosphors is covered with a layer of aluminum 18 which has several functions, including the application of a high voltage of acceleration of the electron beam, the evacuation of the charges which accumulate in the phosphors , the return to the observer of the light which can be emitted towards the interior of the tube by the phosphors.

 In this most conventional embodiment, the aluminum layer 18 also has a function of supporting the beam indexing bands 20. These bands are bands of phosphors preferably emitting in the ultraviolet and distributed with a pitch which is linked that of the strips of phosphors; one can have for example an indexing band every two or three or four bands of phosphors.

 As the indexing strips are carried by the reflective aluminum layer, they emit only towards the inside of the tube. The inner surface of the envelope 10 is preferably covered with a reflective layer, with the exception of transparent zones allowing the exit of the light coming from the indexing strips. Behind these zones are placed detectors 22 which thus collect as large a proportion as possible of the radiation emitted by the indexing strips. It should be mentioned here that the amplitude of this radiation is very low because the intensity of the electron beam is quite low when it passes over the indexing phosphors.

 It is indeed one of the major problems of beam indexing tubes to be able to correctly detect the indexing light pulses which are used for synchronizing video signals.

 One of the limitations encountered with the structure of FIG. 1 is as follows: the indexing bands cannot be wider than the opaque bands 17 because they must not mask the bands of image-forming phosphors 16.

In addition, the indexing bands are defined by photolithography on an aluminum surface that is both reflective and highly diffusing, which affects the quality of the photolithography and requires very large safety margins. This results in either too narrow bands of indexing phosphors providing too low light pulses, or an overall resolution deteriorated if the width of the opaque bands 17 and of the indexing bands is increased.

 This resolution limitation is particularly troublesome for very small screens. However, in some applications (helmet viewfinders, camera viewfinders) we try to have color screens of the order of a few centimeters on the side (an inch on the side for example).

 One of the aims of the invention is to improve the detection of the indexing signal so as not to be hampered by these limitations.

 Beam indexing tubes have already been proposed in which the indexing bands are arranged next to the bands of image-forming phosphors, under the aluminum film and not on this film. The indexing phosphors therefore emit towards the observer. The advantage is that you can have wider indexing bands (the same width as the imaging phosphor bands) without losing much on the resolution. The detected indexing signal is more important. Figure 2 shows this structure. The same references as in Figure 1 are used.

 However, the drawback is that the indexing signal detectors must be placed in front of the screen, on the side of the observer, and even strongly in front to receive the indexing signals emitted from all points in a homogeneous manner. of the screen. The size of the viewing tube can become very large.

 Another drawback is the low photodetection efficiency resulting from the distance of the detectors: in the case where the detectors are placed in front of the screen, there are no reflectors which bring most of the emitted radiation back to the detectors (whereas in the case of Figure 1 we can metallize the interior of the envelope to recover a large proportion of the light emitted).

 An object of the invention is to avoid the drawbacks of the devices of the prior art. We seek in particular to reduce the overall size of the tube, to improve the collection efficiency of the indexing signal, to keep a simple technology, a good spatial resolution of the image, even for very small screens.

 To achieve these goals, the invention provides an electron tube with beam indexing, comprising a transparent screen having an upper surface carrying zones of luminophores for forming light images, and zones of phosphor indexing beams emitting at a wavelength different from the wavelengths emitted by the image-forming phosphors, characterized in that the screen comprises a rear surface constituted by a dichroic filter, essentially reflecting for the wavelengths of the indexing phosphors and essentially transparent to the wavelengths of the imaging phosphors.

 A dichroic filter is a filter having characteristics of light transmission and reflection which depend essentially on the wavelength of the light considered (and which in practice also depend on the angles of incidence of this light).

 It is known to manufacture by superimposing layers of thicknesses and well-chosen optical indices dichroic filters having curves of transmission coefficients and light reflection which vary very abruptly with the wavelength.

 Preferably, indexing phosphors emitting in the ultraviolet will be chosen; phosphors doped with cerium make it possible to obtain emissions in the ultraviolet and are particularly interesting in view of the speed of reaction of this material when it is struck by an electron beam. Except for exceptions, imaging phosphors emit visible light.

 The radiation emitted by the indexing strips is then detected by a detector placed at the periphery of the screen and collecting the radiation exiting through the edge of the screen. This radiation is trapped in the screen thanks to the dichroic filter while the visible radiation corresponding to the light image is transmitted through the filter to the observer.

 The edge of the screen is moreover preferably coated with a reflective layer to increase the proportion of radiation picked up by the detector.

 The image forming phosphors are preferably organized in alternating color bands (in principle a red band, a green band, a blue band). The indexing phosphors are then arranged in bands sandwiched between the bands of imaging phosphors; for example there is an indexing strip every two or three or four bands of image forming phosphors. The electronics for managing video signals naturally take account of the relationship between the periodicity of the phosphor bands and the periodicity of the indexing bands.

 In practice, the bands of phosphors are separated from each other by opaque bands; the indexing bands are also separated from the other phosphor bands by opaque bands.

 Thanks to this new structure, it can be estimated that more than 80% of the light energy emitted by the indexing strips can be recovered by the detector although it is placed laterally with respect to the screen. This makes it possible to benefit from a quite good level of electrical indexing signal without excessively deteriorating the resolution of the image.

Other characteristics and advantages of the invention will appear on reading the detailed description which follows and which is given with reference to the accompanying drawings in which
- Figure 1 and Figure 2, already described, show structures of beam indexing display tubes according to the prior art.

- Figure 3 shows a section of the screen of a tube according to the invention;
- Figure 4 shows a front view of the screen showing the lateral position of the detectors.

 - Figure 5 shows the reflection coefficient curves of dichroic filters as a function of the wavelength.

 In FIG. 3, the same references have been used as in the previous figures to designate similar elements.

 The screen is in principle a transparent glass plate 14 carrying the phosphors on its upper face. The underside comprises a dichroic filter 26 which is essentially transparent for the wavelengths emitted by the image-forming phosphors (in principle visible wavelengths for display screens), but which is essentially reflective for the wavelengths emitted by the indexing phosphors (and preferably for a range of angles of incidence as wide as possible).

 The edge of the screen is preferably coated with a reflective layer 24 to prevent the exit of the indexing light from the edge. This layer 24 covers the screen edge over its entire periphery with the exception of one or more portions in front of which are placed detectors 22 sensitive to the wavelength of the radiation of the indexing bands.

 The image forming phosphors 16 are conventionally deposited on the upper face of the glass plate between opaque strips 17 which are also deposited on the plate.

 An aluminum film 18 transparent to the electrons of the electron gun covers the phosphors to ensure in particular the application of an appropriate potential and the evacuation of electrical charges, but also the return to the underside of the light emitted by the phosphors .

 Between the bands of image forming phosphors 16 are reserved from place to place bands of indexing phosphors 20 emitting at a different wavelength. They are arranged like the strips 16 directly on the glass plate between opaque strips 17. There may be an indexing strip 20 after each strip 16, but more generally an indexing strip will be provided every two or three or four bands of image forming phosphors 16.

 When the electron beam scans the screen surface, it successively strikes bands of phosphors 16 and bands - of indexing 20. The light emitted by phosphors 16 is transmitted to the observer from the side of the underside of the screen (including the fraction of light reflected by the aluminum film). Except for very oblique angles of incidence relative to the underside, this light passes through the dichroic filter 26 and is seen by the observer. On the contrary, the light emitted by the indexing bands in the ultraviolet (for example around a wavelength of 380 nanometers) cannot pass through the dichrolic filter which has a strong power of reflection for these lengths of short wave, even for angles of incidence very close to normal.

 The light coming from the indexing strips will undergo multiple reflections inside the glass plate and will exit through the edge towards the detectors 22.

 FIG. 4 shows how it is possible, for example, to have two detectors 22 facing each other, one on each side of the screen, to collect a larger light signal.

 Since the reflection and transmission coefficients of the dichrolic filter depend not only on the wavelength but also on the angle of incidence, we will calculate this filter so that the reflection coefficient at visible wavelengths is very low up to oblique angles of incidence corresponding to the total reflection at the interface between the upper face of the plate and the air.

 FIG. 5 represents a typical curve of reflection coefficient R of a dichroic filter as a function of the wavelength, for two angles of incidence different from 450 and 800. The wavelength Li designates a wavelength ultraviolet emitted by indexing phosphors. It is known to make such filters by depositing thin transparent layers of thicknesses and optical indices chosen as a function of the desired cutoff frequency for a determined angle of incidence; the cutoff frequency is a frequency at which the filter passes rather abruptly from a mainly reflecting state to a mainly transparent state.

 The opaque bands 17 can be made of chrome; in this case, they are reflective and participate in trapping the indexing light in the glass plate 14.

Claims (5)

 1. Beam indexing electron tube, comprising a transparent screen (14) having an upper surface carrying phosphor zones (16) for forming light images, and beam indexing phosphor zones (20) emitting at a wavelength different from the wavelengths emitted by the image-forming phosphors, characterized in that the screen comprises a rear surface constituted by a dichrolic filter (26), essentially reflecting for the wavelengths of the indexing phosphors and essentially transparent to the wavelengths of image forming phosphors.  2. Electronic tube according to claim 1, characterized in that it comprises at least one detector (22) placed at the periphery of the screen to collect the light radiation emitted by the indexing phosphors.  3. Electronic tube according to claim 2, characterized in that, except at the location of the detector, the edge of the screen is coated with a reflective substance (24) promoting the recovery of light by the detector.  4. Electronic tube according to one of the preceding claims, characterized in that the image-forming phosphors are organized in bands of alternating colors and the indexing phosphors are arranged in bands interposed between the bands of phosphors forming picture.  5. Electronic tube according to claim 4, characterized in that the bands of image-forming phosphors and the bands of indexing phosphors are separated from each other by opaque bands.