DE2823656C3 - Display device with a light-emitting diode matrix for displaying simple characters, as well as use of the display device in a shot simulator - Google Patents

Description

40 The invention relates to a display device for two-dimensional representation of simple characters varying shape, size or location with a light emitting diode matrix are in the arranged light-emitting diodes in the form of rows and columns and connected in each row and column to a common row or column line, a control device which is connected to the row and column lines and has the following units: a read-only memory with the stored bit combinations corresponding to the character elements to be displayed, each character element comprising one or more light-emitting diodes of a row or column, and a control unit such that the display of the entire character is carried out by cyclically successive display of the corresponding character elements and in each case all light-emitting diodes forming a character element are activated simultaneously (time-division multiplex control).

A display device of this type is from W, Schmidt / O. Feustel: Optoelectronics Würzburg 1975, VogeUVerlag, S, 237 to 247 known. In this known display device, the lines of light emitting diodes or ^ columns controlled sequentially The consequence of this is that a Number of scanning steps is required, which is equal to the number of columns or rows. Do also have to

Rows or columns are scanned that contain no character element, so that a total of unfavorable duty cycle and accordingly a limited brightness of the display results

The invention is based on the object of determining the pulse duty factor in a display device according to to improve the preamble of claim 1 and thus to increase the sampling frequency, thereby also when displaying several independent characters in the same display image, a stationary, never-free image to can be reached.

According to the invention, this object is achieved by that the display device of the type mentioned above has the following characteristics:

That the memory contains the bit combinations which correspond to those character elements that result when the character to be displayed is broken down into as few character elements as possible, both columnar and cellular character elements can be stored, all bit combinations can be addressed independently of one another by the control unit, and in the time division multiplexing Control only d ^{: A} few rows and columns are included that have a character element of the character to be displayed.

From DE-OS 25 19 020 is for the case of static control of a liquid crystal display matrix the representation of simple characters is known.

Since, according to the invention, only those rows and columns are included in the time division multiplex control, which have a character element of the character to be displayed and there the characters to be displayed are broken down into as few character elements as possible, are only used in this way for the representation of a character many scanning steps are required as there are drawing elements. This number is much less than the number of rows or columns in the matrix. It follows that the individual drawing elements with greater Frequency and accordingly shown with greater brightness and a more favorable duty cycle can be n. Since the scanning frequency is significantly increased, it is also possible to use several independent characters, each consisting of individual drawing elements, to be displayed on the display matrix at once and still achieve a steady, flicker-free image.

The brightness of each character element can be controlled by varying werJen dt: system time of the address signal to the memory and / or drives by clocking the supply voltage of the light-emitting diodes and / or controlled by selection of an idle address of the memory that none of the diodes.

The stored drawing elements can be the representation of a display mark of the same Shape but different position or an indicator mark of the same shape but different Size on the diode matrix.

According to the invention, this display device can be used in a shot simulator, the one Transmitter for sending out sharply bundled light signals and an evaluation device for determining the Storage between the light signal received at a target or retroreflected from the target to the transmitter and has a line of sight. In this use, the address connected to the storage evaluation device Control unit the Zeicherielerriefite deposit-dependent in such a way that they have a character that is shifted relative to a center point in accordance with the filing represent.

In addition, according to the invention, the display device can be used in a gunshot simulator, one connected to a target rangefinder Control unit additional drawing elements of a distance-dependent enlarging or reducing Character addressed and a control device cyclically alternating the addresses for the simultaneous Display the storage-dependent and distance-dependent characters in the memory

The control device can control the system time of the individual addresses in such a way that the various Characters are displayed in different brightness.

Furthermore, the display device according to the invention can be used in a shooting simulator for shooting guided missiles are used, with the continuous emission of light signals and permanent Storage and, if necessary, distance determination works Here, the display device is used to generate a signal during the simulated flight time changing appearance.

An embodiment of the invention is based on the Drawings explained in more detail.

F i g. 1 shows schematically a light-emitting diode matrix with a control device;

F i g. 2 shows the image field formed by the light-emitting diode matrix with various representable Sign;

F i g. 3 shows schematically a shot simulator with an evaluation device and a connected inventive device Display device.

According to FIG. 1 are light-emitting diodes 10 electroluminescent diode ^ LED) in the form of a matrix with z. B. 5 columns a, b, c, rf and e and 4 rows 1, 2, 3, 4 arranged. This small number of columns and rows was chosen here for the sake of simplicity, in reality the display device is a much larger number of light emitting diodes have, e.g. B 1024 diodes arranged in 32 rows and 32 columns.

Each light-emitting diode 10 is on one side with a column line common to all diodes of a column 12 and connected on the other side to a row line 14 common to all diodes in a row. All column lines 12 are connected to a common voltage supply line 18 via switching transistors 16 connected to which a constant potential is applied. All cell lines 14 are also via switching transistors 20 connected to a common line 22 which is at a different potential, e.g. B. at Earth potential. The switching transistors 16, 20 are normally in the blocking state and can through their Control signals supplied to bases are controlled into the conductive state. Each light emitting diode 10 can light up only when both the switching transistor 16 in the associated column line and the Switching transistor 20 was controlled in the associated row line in the conductive state.

The switching transistors 16 and 20 have their bases connected to the outputs 2 ^{C of} a programmable read-only memory 26 (PROM). The number of outputs 24 of memory 26 is thus equal to the sum of the rows and columns of the diode matrix. A multiplicity of different bit combinations, each with an associated address, can be stored in the memory 26, the number of bit positions in each bit combination being equal to the number of outputs 24. Depending on the bit combination present at the outputs 24, the individual switching transistors 16, 20

locked or opened so that one or more light emitting diodes 10 can be made to light up in any row or column of the matrix at the same time. Each bit combination thus represents a representable character element, e.g. B. a point or a horizontal or vertical line on the display panel. In order to display any of the stored character elements, only the associated address needs to be entered into the memory by a control unit 30 connected upstream of the memory 26 *, whereby the bit combination corresponding to the character element appears at the outputs 24 of the memory. If a character composed of several stored elements is to be displayed, the addresses of the individual character elements are supplied one after the other at a frequency adapted to the inertia of the human eye. For each individual character element the rolotiwo Ι-ΙαΙΙίηΙοι * / 4tir /> H A \ t * \ A'a \\ V \ a \ tt * '\ i cpinf> r Anctpitp.

tion and / or can be influenced by the different duration of the supply of the address.

In Figs. 1 and 2 examples of stored character elements are given. It is assumed that the switching transistors 16, 20 block when the bit level 0 appears at the memory output 24 connected to their base, while they are conductive at bit level 1 (of course the relationships could also be reversed). The bit locations reserved for the binary-coded addresses are indicated on the left-hand side of the memory 26. At address 1 is z. B. a bit combination is stored in which all outputs have the level O, so that all transistors are blocked and the entire diode matrix is dark. A bit combination is stored at address 2 in which z. B. all diodes in column b light up, so that the stored and displayed character element is a vertical line 32 (FIG. 2). A bit combination is stored at address 3 in which all diodes in the second row of the matrix light up, that a horizontal line 34 is shown as a character element. Together, the character elements 32, 34 result in a crosshair with a specific position on the screen 31 formed by the diode matrix, this crosshair being represented by rapidly changing addresses 2 and 3 to the memory 26. The diodes forming the crosshairs are controlled in a test ratio of 1: 2, so that a very good brightness yield results. No time is required to control diodes that do not belong to the character to be displayed.This means that the method of operation of the diode matrix according to the invention differs in an advantageous manner from a line-sequential individual control of the diodes, in which the duty cycle for the control of each individual diode is 1: m χ π would be if m and η are the number of rows and columns, respectively, of the matrix. In the operating mode according to the invention, on the other hand, the duty cycle is given by 1: N. If N is the number of stored character elements that make up the entire character. In the case of the cross consisting of a horizontal and vertical line, N = 2.

Character elements can be stored under additional addresses that contain e.g. B. the horizontal and vertical lines 32, 34 in a different position, so z. B. in the i, 3rd and 4th columns or ί, 3rd and 4th etc. ». Ζεϋε correspond, so that by appropriately combining two different addresses, the crosshair can appear in any position on the display panel 31. So you can with the Bar cross as a mark any filing from the center of the display field 31 according to size and Illustrate direction clearly.

Another character that can be represented in this way is indicated in Fig.2 by the horizontal lines 36 and vertical lines 38, which together a delimit rectangular field. Each pair of lines 36 or 38 is a character element under an address saved so that the entire rectangular figure consists of two drawing elements. Do you want the rectangle together with the crosshair at the same time, the addresses of a total of 4 character elements are fed to the memory 26 in cyclical order. Lines 36 ', 38', which delimit a larger rectangular field. One can thus on the display panel 31 Here the relative position of the line cross 34 or its point of intersection in relation to a distance-dependent Show target object that appears larger or smaller.

Of course, the number and type of storable and displayable character elements are not limited to the embodiment described. For example, drawing elements consisting of a single diode can also be stored. An example! this is indicated in FIG. 1 at address 4, where the associated bit combination controls the lighting up of the diode in column b and row 2.

Γ i g. 3 illustrates the use of the display device according to the invention in one with Light signals working shot simulator. The shot simulator comprises a z. B. with a training weapon coupled visor 40 and a laser transmitter 42 adjusted axially parallel to the visor 40. The laser transmitter 42 sends sharply focused laser light signals 44 either simultaneously or in rapid succession, 44 'from. the different angular deviations according to height and side from that parallel to line of sight 45 Have transmission axis 46. The respective angular deviation of the laser light bundle 44 ′ from the transmission axis 46 is z. B. characterized by a time code or by a pulse code impressed on the laser light signal On a target object 48 there is either a receiver for the laser light signals or a retroreflector (Triple mirror reflector) is provided, which reflects the light signal back to the laser transmitter 42 in the same direction where a receiver 50 is provided Depending on how exactly the line of sight 45 and the line of sight to it when shooting parallel transmitter axis 46 was aligned with the target 48, the target becomes larger from a light signal 44 ' or a smaller angular deviation from the axis 46 can be met. The information about this angle deviation is z. B. in the pulse coding or time allocation of the received from the receiver 50 Contain reflection signal and is detected in a decoder 52 connected downstream of the receiver 50 and an evaluation device 54 which also contains a start pulse from the laser transmitter 42 and which Angular offset determined numerically according to size and direction. Around these numerical values on the display device 31, the numerical values determined are fed to an address converter 56, which generates those addresses among those in the memory 26 the character notes that have a corresponding displaced cross lines 32,34 on the display field 31 form, are stored. These addresses, e.g. B. for the

The position of the horizontal and vertical lines are fed to the memory 26 by means of the control unit 30 so that the corresponding drawing elements are called up and the crosshair 32 ₍ 34) is displayed on the display device 51 so that its displacement relative to the center of the display field is determined by the evaluation device 54 W-article deviation of the "shot" corresponds.

06 the ascertained and displayed angular deviation or position in relation to a hit or miss speaks, can often erv in practice; then judged when the size and distance of the Zielobjeklcs is also known and shown. A given angular deviation may be at a nearby and therefore an apparently larger target still a hit, at a distant one and therefore apparently smaller target mean a miss. In the case of the flow simulator according to FIG. 3 is therefore a distance (tif ^ ocAr ? C wnfnAcoKon rl Ar oho / Ιαγ I anfvntt H ** c wvm * 7i * »l

48 reflected and received by the receiver 50. The target range is determined Memory 26 are stored drawing elements which together form a rectangle area on the display screen 31 before 19 or 39 'result in different sizes. This Rectangle schematically represents the apparent size of a typical target object, e.g. B. an armored vehicle, in different distances. An address converter 60 connected downstream of the range finder 56 Depending on the distance determined, it generates addresses that are also sent to the memory 2ö JO via the control unit 30 ζ are guided and there call those drawing elements that have a rectangle 39 in the measured Distance represents corresponding size. The control unit 30 leads the memory 26 according to the The addresses for the display of the crosshairs 32, 34 and for the Representation of the rectangle 39 so that both characters appear on the display screen 31 at the same time. The address system time can be set by the control device 30 be chosen so different for the individual character elements that the crosshair appears with significantly greater brightness than the rectangle 39 and can therefore be easily distinguished from it is. To adapt the brightness of the entire display to the ambient brightness In addition, the matrix brightness can be set by means of an adjustable, clocked selection of an empty address (Fig. 1, Addr. 1) can be controlled at will. This brightness control can also be done by clocking the LED supply voltage take place.

If, for example, the range finder 56 determines a target range of 2000 m, the address converter 60 generates those addresses which correspond to the representation of a relatively large rectangle 39. In this case, the intersection oes reticle 32.34 is within the rectangle 39 so that it can be seen that the target was hit. If, on the other hand, the measured target distance is z. B. 3500 m, so the character elements for a correspondingly smaller Redhteck 39 'are called from the character stock in memory 26, so that it can be seen that, for. B. in this case the intersection of the crosshair is outside the target, so that a miss can be detected.

A shot simulator of this type is particularly advantageously used for simulating steered Anti-tank missiles. In this case, it is not only important that the visor 45 at the moment of Firing is correctly aimed at the target 48, but the sight 45 must during the entire Flight line of the guided missile, i.e. for several seconds, aimed at target 48 and be tracked. Through ongoing generation of the Light signals 44, 44 '. ongoing determination of the target filing and target distance and ongoing display of the relative position of the stopping point (intersection of the line cross) and the in its apparent size target shown on the display screen 31, such shooting can be practiced and simulated and constantly the Assessment of the deviation of the stopping point from the target

The display device according to the invention has the advantage that it is a compact and robust unit can be trained. The light-emitting diode matrix is of course covered by a window which preferably a distance of at least 1 mm from the light-emitting diodes. The control devices for the Light-emitting diode matrix, in particular the programmable read-only memory 26, the address converters 58, 60 and the control logic 30 controlling the supply of addresses can be in the form of integrated circuits will. The memory 26 can also be composed of several integrated units. For example are memories with eight connections, i.e. eight bit positions for each addressable memory location, and with z. B. 512 addressable memory locations available on the market. For controlling a diode matrix of e.g. 32 rows and 32 columns, i.e. 1024 diodes, you need a memory with 32 + 32 = 64 Exits. Such a memory can be integrated in parallel by connecting eight of the above-mentioned Represent memories with eight outputs each. The same is then in each of the eight memories Address a part of the total of the character element to be represented forming bit combination is stored and when this address is entered at the same time in all eight memories at the assigned outputs provided.

In order to enable a subsequent assessment and control of the shooting result, the results determined by the deposit evaluation device 54 and the range finder 56, namely expediently in the form of the addresses generated by the converters 58, 62, temporarily stored in a memory 52 so that they can then be used at any time, e.g. B. even after the exercise has been completed Playback mode can be called up and fed via the control logic 30 to the memory 26, which then the corresponding representation is generated on the display panel 31

Instead of a programmable read-only memory (PROM), a permanently pre-programmed (mask-programmed) read-only memory (ROM) can be used.

For this purpose 2 sheets of drawings

Claims (9)

15 20 claims: 1. Display device for two-dimensional Representation of simple characters of changing shape, size or position with a light-emitting diode matrix in which the light-emitting diode !! in the form of Zsilsn and Columns arranged and in each row and column to a common row resp. Column lines are connected, a controller connected to the row and column lines, and which has the following units: Zl a read-only memory with the drawing elements to be displayed corresponding stored bit combinations, with each character element one or more light-emitting diodes a row or column, 2.2 a control unit in such a way that the display of the entire character takes place through cyclic successive display of the corresponding character elements and all light-emitting diodes forming a character element are activated simultaneously (time-division multiplex control),
characterized by the following features: The memory (26) contains the bit combinations (addr. 1, addr. 2 ..), those Character elements (32, 34; 36, 38) correspond to the decomposition of the Character (32 mn 34, 36 with 38) result in as few character elements as possible (32, 34; 36,38), ' both columnar (32, 38) and cellular (34, 36) character elements can be saved, all bit combinations (addr. 1, addr. 2, ...) are independent of each other Control unit (30) addressable, and only those rows and columns are included in the time division multiplex control which have a character element of the character to be displayed. 2. Display device according to claim 1, characterized in that the brightness of each of the Simultaneously controlled light emitting diodes formed character elements by changing the installation time of the address signal on the memory (26) can be controlled. 3. Display device according to claim 1 or 2, characterized in that the stored Drawing elements the representation of an indicator mark of the same shape, but different Position on the diode matrix. 4. Display device according to one of the claims to 3, characterized in that the stored character elements represent a display mark of the same shape but of different sizes on the diode matrix, 5. Arizeigevöfrichlürig according to one of the claims 1, 3 or 4, characterized in that the brightness of the ¹ represented characters is controllable by clocking the supply voltage of the light-emitting diode "Lind / odcf" through the controlled selection of an empty address of the memory which does not drive a diode 6. Use of a display device according to one of claims 3 to 5 in a shot simulator, one transmitter for sending out sharply focused light signals and an evaluation device to determine the storage between the transmitter received at a destination or from the destination having retroreflected light signal and a line of sight, characterized in that the to the Filing evaluation device (54) connected control unit (58) the drawing elements (32, 34) Dependently addressed in such a way that it has a corresponding to the deposition opposite a center point represent displaced character. 7. Use according to claim 6, characterized in that one to a target range finder (56) connected control unit (60) additionally the drawing elements of a distance-dependent enlarging or reducing character (39) addressed, and that a control device (30) cyclically alternating the addresses for the simultaneous display of the storage-dependent and distance-dependent characters (36,38 or 39) the memory (26) supplies 8. Use according to claim 7, characterized in that;: xaß the control device (30) the System time of the individual addresses controls in such a way that the characters (36, 38 or 39) in different Brightness. 9. Use according to one of claims 6 to 8 in the case of a continuous emission of the light signals and shot simulator that works continuously to determine the position and, if necessary, to determine the distance for guided-missile shooting to generate a down during the simulated Flight time changing representation.