DE2461719A1 - DATA DISPLAY DEVICE - Google Patents

Description

DIPL.-CHEM, W. RÜCKER DIPL ..- ING. S. LEINE PATENT LAWYERS

3 HANNOVER, BURCKHARDTSTR. 1 TELEPHONE CO51 »62 84 73 ■

• EMI Limited Our mark 100/435

Date 2 December 7th 1974

Data display device

The invention relates to a data display device. the The invention particularly, but not exclusively, relates to such arrangements in which data obtained from an infrared scanning device is transmitted via a scanning transducer system are fed .sind into a display device with a cathode ray tube which deflects in a television raster format is.

In some cases it is desirable that the display device not display the entire field of view of the infrared scanner device, but rather be used to do so can reproduce only part of the field of view with the grid of the same size in order to achieve a so-called "zoom" effect as a result.

The invention is based on the object of creating a data display device in which this possibility exists.

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The object on which the invention is based is achieved by a field of radiation-sensitive detectors for recording of radiation from corresponding linearly arranged areas of one scanned by the radiation within the areas Scenery, through a display device with a cathode ray tube for displaying the output signals in the form signals related to a raster, with different lines of the raster being assigned to respective linear regions, by a converter device for processing the output signals, which has scanning means for scanning the output signals, control means for controlling the Speed at which the scanning device operates, and a counting device which is designed so that a fixed number of samples of each output signal reaches the reproducing device regardless of the sampling speed, creating an electronic zoom effect in the direction of parallel is achievable for the lines of the grid.

The invention is to be explained in more detail using an exemplary embodiment with the aid of the drawing.

1 shows, as a block diagram, a data reproduction device according to an exemplary embodiment the invention,

2 (a) and 2 (b) illustrate schematically different possibilities of scanning or Interrogation of the output signals of the detectors according to FIG. 1,

Fig. 3 also shows schematically as a block diagram "

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a part of the arrangement according to FIG. 1 in detail, and

Fig. 4 shows an interpolation arrangement as used in the invention.

In Fig. 1 , infrared radiation, which comes from a defined field of view, for example 14 ° in height and 2 0 ° in azimuth, is received by the arrangement via an input window 1, which can be equipped, for example, with options (not shown) for heating like. The radiation is scanned in azimuth by means of a horizontal scanning arrangement 2 which, for example, may have a multi-facet drum arrangement. The radiation falls on a vertically arranged field 3 of a hundred infrared-sensitive detectors. The detectors thus receive radiation from associated linear areas within the field of view, the areas being at a distance from one another in height. A refractive wedge 4 operates in synchronism with the operation of the horizontal scanning assembly 2 and provides a small amount of elevation shift after each completed horizontal scan so that intermediate data can be derived from the detectors. The output signals from the detectors are successively sampled at high speed by a multiplexing system 5, the arrangement being such that the output signal of each detector is sampled, in this case 512 times, during a single horizontal scan by the sampling arrangement 2. Thus it follows that the of the field

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Scanning signals supplied by detectors are scanned "vertically" - i.e. that the multiplex system 5 - successively - a first interrogation from the first detector, a first interrogation from the second detector, a first interrogation from the third detector, etc., and after the first poll of all two hundred detectors, returns to one make a second interrogation from the first detector. These Form of operations, 512 in this example, is performed during each horizontal scan period.

The multiplex output signals are converted into digital signals by one or the other of two analog / digital converters 6 and 7. One of the A / D converters 6 and 7

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operates output signals derived from / even detectors, and the other A / D converter processes the Signals derived from even detectors. The digitized output signals are then passed to associated addresses in a memory 8, which is part of a Standard converter 9 is. The standard converter 9 converts the output signals from the detectors into a format that with a conventional C.C.I.R. television picture with 625 lines per Image (585 effective lines) and a vertical scanning speed of fifty frames per second. The memory 8 of the standard converter 9 preferably has a large number of memories with direct access (RAM), which are filled at one speed with the digitized signals and with a sequence and thus queried

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can, 'that the stored information can be queried at a different speed and a different order. Converted output signals are applied via a digital / analog converter 10 to a display device 11 having a cathode ray tube, which is a conventional television display tube. The working circuits of the converters 5, 6, 7 and 9 are controlled by a main clock generator 12, which preferably also serves to control the derivation of the scanning waveforms which are applied to the scanning coils of the display tube 11.

As far as the arrangement has been described so far, it is not able to enable a zoom effect, that is to say that the relationship between the field of view and the display grid is constant. It is a special feature of the arrangement so far described, however, that the resolution of the output signals from the detectors is higher than that required for the 512 interrogations mentioned and sufficient to increase the interrogation speed to 1024 ptD horizontal scanning. In simple terms, this means that only half of the available resolution is used in the horizontal direction - as is illustrated in FIG. 2 (a), which schematically shows a strip of the field of view seen by a detector. The strip is alternately separated by circles and squares, each representing a dissolvable element. The circles represent resolvable elements that deliver output signals that are queried by the multiplex system 5, while the squares are independent.

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represent requested elements. In Fig. 2 (a) only eight resolvable elements are shown for the sake of simplicity, in fact there are 1024 such resolvable elements. The overall sensitivity of the system is 512 elements per line ,, and according to this embodiment of the invention is achieved, a horizontal zoom characterized in that adjacent up 512 * releasable elements are queried that the field of view are arranged centrally in _t. This means that 206 resolvable items on either side of the central district are not queried. This is shown in simplified form in Fig. 2 (b), in which the group of four adjacent and centrally arranged circles are interrogated elements and the pairs of squares lying on either side of the group of circles are unsolicited elements represent. By comparing the number of circles ^ in Fig. 2 (a) and 2 (b) it can be seen that the same number of resolvable elements is queried in each case.

It thus follows that by appropriate timing and changing the polling speed of the multiplex system 5 all the 512 elements, which occupy the full width of the grid on the display tube 11, can be derived from the central zone of the field of view and a horizontal zoom is thus achieved.

Part of the device for achieving the horizontal zoom is shown in FIG. A zoom control box 13 has two controls a_ and b_, one to determine the distance

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the one from the edge of the field of view at which the interrogation or scan is to begin and the other to determine the scan speed. A (not shown) Locking eggs on the horizontal scanning arrangement are used to generate 1280 pulses per horizontal scanning, these Pulses are used to phase-lock an oscillator 14 which, in this example, delivers eight times as many pulses per horizontal scan - 10240. The high-speed pulses from the oscillator 14 are transmitted via a Module-n divider circuit 15 and an AND gate 16 are fed into the multiplex system 5 (see FIG. 1). The division ratio of the Divider circle 15 is set by the controller b_ for the zoom. The pulses from the oscillator 14 are in one Counter 17 counted and compared in a comparison circuit 18 with a number that is determined by the setting of the controller a_ for the zoom is determined. If the comparison circuit 18 establishes equality between the two stored signals, it generates an output signal that takes a bistable circuit 19 into its "1" position, in which it receives a preparation signal the AND gate 16 supplies. This enables forwarding of pulses from the divider circuit 15 to the multiplex system. These work pulses also reach a counter 20, the counts to 512 (the number of inquiries - which remains fixed) and then sends a reset signal to the bistable circuit 19. This interrupts the feed of work pulses into the multiplex system.

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It should be noted that the controls a_ and b_ for zooming are independent, as it is for the Abfragegeschwin the multiplexer speed required to rise · if the start of the sampling period toward coincidence with the center of the horizontal scanning moves (the Coincidence is of course never reached). The horizontal zoom is thus carried out before the scan conversion takes place. However, the vertical zoom that occurs is effected after the scan conversion (and before the digital to analog conversion) by interpolation between the lines of video information coming from the scan converter.

FIG. 4 is a block diagram showing a vertical zoom arrangement for use in this embodiment of FIG Invention. Data from the scan converter (not shown in Fig. 4) enter a shift register 21 which has storage locations for 512 pixels, i.e. one line of video information. the Information in this shift register can either be newly stored via a connection 22 or in the input of a ' further identical shift registers 23 can be stored via a connection. The shift register 23 also has one Return path 25. If the two return paths are interrupted, data is entered into the shift register 21 of the interpolator in the form of a line of an even-numbered field of the Display raster and an adjacent line of an adjacent odd-numbered field, the arrangement is made in such a way that the first line of the two is replaced by the Shift register 21 runs into shift register 23. The second

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Line of the two is held in the shift register 21. The output signals of the two shift registers are fed into a digital subtraction circuit in which the in one Memory stored data can be subtracted, a Pixel at a time, from the data stored in the other shift register. The single line of information of the output signal from the subtracting circuit 26 is divided by an integer, e.g. 16, in a divider 27, the Factor 16 is chosen for the sake of simplicity in this example, since it gives sufficient accuracy for the interpolation process. It should be noted, however, that the factor 16 is in no way essential to the invention.

The output from the divider 27 is then multiplied in a circle 28 by an integer between 1 and 16 inclusive and is determined by a number selected from a read-only memory (ROM), which is previously designed so that it has the correct interpolation coefficient for each line circle 29 by means (not shown), which are coupled to the display line counter. The output of the multiplying circuit 28 is in an adder 30 to the current The output of the shift register 23 is added, so that a new interpolated line of video signals is created which is then converted into analog form and fed into the cathode ray output device.

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Of course, each level in the zoom requires a ROM, so eight ROMs are required for an eight-step zoom, with the appropriate one for the particular zoom setting by the Zoom controller 13 is selected.

Under certain zoom conditions (especially at maximum magnification) it is necessary to derive new display lines from exactly one pair of adjacent lines as they get into the shift register. For this reason the shift registers 21 and 23 are provided with their respective connections 22 and 25 for feedback. These return paths are controlled by a connection 31 through the read-only memory 29. The circle 29 is re-addressed for each display line: The value of the multiplier coefficient suitable for each line is preset by the line circle 29 .

Even if the previous statements on height and Azimuth and horizontal and vertical scan directions are not limited in any way to the invention to a certain orientation.

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Claims (7)

Claims [J /. Data display device, characterized by a field of radiation-sensitive detectors for receiving radiation from corresponding linearly arranged areas of a scene scanned by the radiation within the areas, by a display device with a cathode ray tube for displaying signals related to the output signals in the form of a grid, with various Lines of the raster are each assigned to corresponding linear regions, by a converter device for processing the output signals, which comprises scanning means for scanning the output signals, control means for controlling the speed at which the scanning device operates, and a counting device which is designed so that a fixed number of scans of each output signal reaches the display device regardless of the scanning speed, whereby an electronic zoom effect can be achieved in the direction parallel to the lines of the raster. 2. Data display device according to claim 1, characterized by scanning means for scanning the radiation impinging on the radiation-sensitive detectors. 3. Data display device according to claim 2, characterized in that the scanning device is a multiple faceted 509828/0661 Has drum device. 4. Data display device according to one of the preceding claims, characterized in that the converter has a memory arrangement with a plurality of memories with direct access. 5. Data display device according to one of the preceding claims, characterized in that the control device is additionally designed so that it controls the deviations of scanning waveforms which are applied to the cathode ray tube of the display device. 6. Data display device according to one of the preceding claims, characterized by an interpolation device for interpolation between lines of information which are essentially identical to associated lines of the grid, whereby a zoom effect can be achieved in a direction perpendicular to the lines of the zoom. 7. Data display device according to claim 6, characterized in that the interpolation device has means for deriving two additional display lines from a pair of adjacent display lines as obtained from the converter. 509828/0661