SU633042A1 - Arrangement for displaying information on tv indicator - Google Patents

Description

(54) DEVICE FOR DISPLAYING INFORMATION ON SCREEN OF TELEVISION INDICATOR

horizontal and vertical sampling and a basic parameter memory block, an image device connected to the character generator and arcs and vector coordinates calculation units, a decoder connected to the main parameter memory block and a coding unit connected to the image device and a television indicator.

The invention is illustrated by the drawings, where in FIG. 1 is a functional diagram of the device; FIG. Figure 2 shows an example of shaping a complex image.

The proposed device consists of input | 1 b | 1, connected to the memory of input signals 2, connected to output block 3 and subtractor of basic parameters 4, clock generator 5, connected to vertical counters 6 and horizontal 7 sampling, connected to the generator characters 8, the main parameters memory block 9, connected to the main parameters calculation block 4, the addresses forming coordinates on coordinates 10 and 11, connected to the main parameters memory block 9 and respectively to the counters ontal 7 and vertical 6 sampling serially connected blocks for calculating the coordinates of arcs 12 and vectors 13, connected to horizontal and vertical sampling counters and a block of basic parameters, an imaging unit 14 connected to a symbol generator 8 and blocks for calculating coordinates of arcs and vectors, a decoder 15 connected to the basic parameters memory unit 9, and the coding unit 16 connected to the imaging unit and the television indicator.

The proposed device works as follows.

A conventional input unit 1, represented as a light, ultrasonic, or contact pen, enters graphic information into a storage unit of input signals 2. As input signals, we assume the coordinates of the extreme points of the vector, or three arc points, or a character code combination.

The input signals are usually presented as a complete list of full-graphic data for each sign, vector, or arc in real coordinates, as is done in conventional beam-controlled displays.

The input signals through the output unit 3 can be fed to the line for transmitting data to remote computers or to similar information display devices.

From the second output of the memory block of signals 2, the source data is alternately supplied to the basic parameters calculation unit 4, which produces a recalculation of the input parameters into the basic parameters necessary for the further formation of the image only within the selected zones.

The basis of the construction of the proposed device is the choice of a large number of identical square zones located on the active part of the raster. When forming the alphanumeric information, these zones perform the functions of sign rectangles into which the characters of the generated characters are respectively entered. Since these zones are included in a rectangular grid into which the entire raster can be divided, the location of these zones is well defined. When forming alphanumeric information, the symbols of which have a fixed position in the selected zones, there is no need to memorize the address of the sign. In such cases, only a character code pattern is inserted into the zone memory, which is then converted into a video signal in a known manner.

When generating graphic information, a vector passing through two points, or an arc, depending on its size and location, is located on a certain number of square zones. Naturally, in the memory of all these zones it is necessary to enter codes that characterize the type of the formed image, and its basic parameters, the nature of the coding, etc.

In the process of sequential reading of information from all zones, as is done in alphanumeric displays, at the output of the basic parameters memory block 9, the code combinations describing one or another element of the common image are interpreted in the same way as in alphabetic digital or graphic display devices.

For this purpose, a sign generator 8, a unit for calculating the coordinates of arcs 12, a unit for calculating the coordinates of vectors 13, a decoder 15, etc. are used.

The number and type of computing devices is determined by the nature of the basic parameters and the chosen algorithm of operation of the entire device as a whole.

Claims (2)

For example, when reproducing two vectors intersecting at one point, or a broken line, the place of the break of which can be considered as a point from which two vectors diverge, it is necessary to use two units for calculating the coordinates of vectors working non-escape from each other. When displaying three lines within one zone, three units for calculating the coordinates of vectors are required. The use of independent shapers of intersecting shapes is due to the fact that when editing a generated image, erasing or moving one of the shapes does not violate the composition consisting of the left shapes, i.e. . does not exclude from the remaining image the common elements belonging to the excluded and remaining images. The number of vectors crossing one zone is usually determined by the size of this zone. Therefore, it can be argued with high confidence that the number of computing devices of this kind is the smaller, the greater the number of zones located on the television image. When selecting the maximum possible number of zones, as is done for alphanumeric displays, the number of calculation units or vector coordinates can be limited to two or three, and the units for calculating arc coordinates can be limited to one or two. The remaining operations performed by the imaging unit, the decoder and the encoding unit, in principle, do not differ from the known ones. The basic parameters calculating unit 4 operates at a relatively low speed. At its output, the result of the calculation does not change during the entire recording time, which makes it possible to record the main parameters in all the cells of the field that correspond to the zones through which the graphic element passes. For definiteness, it is necessary to form a graphic image consisting of the vector , an arc and three characters, as shown in Fig. 2. In this case, in principle, any of the known methods can be used to write information to the memory. However, the recording of graphic information in the memory module of the main parameters 9 can be performed automatically. For example, when recording vector information, the coordinates of the beginning and end of the vector are entered in the memory of the input signals. Based on these data, calculation unit 4 not only calculates the main parameters, but also calculates the address of the cells into which these parameters are to be written, that is, in addition to its main function, it performs a calculation similar to the units for calculating the coordinates of arcs 12 and vectors 13. Thus, information on the basic parameters of the generated vector will be written in cells, in the memory block of the main parameters. isPs (Fig. 2). Similarly, the information about the main parameters of the arc will be recorded in the cells, iijpj; rn / pj, the program of operation of block 4 provides for the following sequence: the main parameters are initially calculated, and then all the coordinates of the zones (ad-, ree) on which these parameters should be written. Naturally, at the second stage of calculations, the value of the main parameters is constant and reads from the register to the memory as the coordinate values are entered. It is quite clear that only the old bits of the address are used as the address of the record, since in this case the recording is carried out in the zone cells. The basic parameter memory 9 is essentially a regenerative storage device operating synchronously with the television sweep speed. The nature of his work is no different from the operation of the buffer memory of alphanumeric displays. The number of memory cells in this memory is determined by the number of zones into which the entire raster is divided, and the capacity of each cell is determined by the amount of information required to reproduce alphanumeric and graphic images of the selected complexity. Since in this device there is a possibility of using the method of similar multiplication which allows to significantly reduce the memory capacity of block 9, consider this in more detail. Suppose, when displaying the information recorded in the zone gti pj (figure 2), it is necessary to form a segment and part of the arc bounded by the boundaries of this zone. If the main parameters of these graphic elements are represented by a full 10-bit code, and in the process of forming these elements, calculating blocks 12 and 13 also submit the full digital sweep functions of the horizontal TSRF and the vertical TSRF of discretization, then it is not difficult to see that the result of such formation is limits of the selected zone, determined by the change of only the lower bits. But since information about the configuration of the formed elements is laid in the memory of this zone, then this information should be decrypted only within this zone. In other words, the basic parameters in block 9 can be represented only by low-order bits - (3-4 bits - according to the number of bits involved in the decoding of information inside the zone). In this case, the gain in the storage capacity will be 3.32, 5 times, respectively. Therefore, to the input of blocks 12, 13, 8, signals are taken that are taken from the information outputs of the counters of horizontal 7 and vertical b sampling. The character of the generated similarly multiplied images with the elimination of the higher bits in the list of the main parameters of the generated images and digital scanning functions (CRF) of computing devices as an example is shown in the upper left corner of FIG. 2. The presence of a large number of zones on which there is no graphic information allows, in a queue, to use this phenomenon to reduce the capacity of the memory block of the main parameters. For this purpose, a space code is entered into the memory cells indicating its interval from the end of any image to the beginning of the next image. The use of quasi-associative memory for this purpose avoids the uneven filling of the cells, which ultimately leads to significant savings. It remains to add that the address buses of the readout of the memory of the main parameters are supplied only to the higher bits of the corresponding address CRDs taken from the address generation counter along the X 10 coordinate and the address generation counter along the H 11 coordinate. Only the lower ones are fed to the inputs of the calculation blocks B and 7 bits of the corresponding CRPs. Naturally, such an approach leads to a significant simplification of the computing units of the coordinates of arcs 12 and vectors 13. The fact that the computation time during image generation is significantly reduced is also positive, since Basic digital operations are performed with words of minor length. This in turn simplifies the speed requirements of digital elements. The combination of functions of an alphanumeric display with a graphic, in a considered device, is associated with some specific features of the choice of a digital sweep function of vertical sampling. The fact is that when displaying alphanumeric information, the origin of coordinates is advisable to choose at the beginning of the forward stroke of the vertical sweep (upper left corner of the raster). With such a choice of the origin, it is necessary to ensure the usual text entry procedure for European languages (from left to right and from top to bottom) However, such a choice of the origin of coordinates in graphic displays is inappropriate, since this necessitates entering a number of parameters with negative signs. The choice of the origin for displaying graphical information in the lower left corner can be achieved by using subtractive counters as CRFs. To do this, during the reverse frame scan, counters 6 and 11 are written to In the process of vertical scanning, the horizontal sync pulses are fed to the subtracting input of the counter, the value of which varies linearly to zero in the lower part of the raster. The latter should be taken into account when synthesizing characters, and also when selecting signals readout addresses supplied to the memory of the main parameters 9. The output signals of the memory of the main parameters 9 are divided into groups depending on which bits of the memory cells are written and information is needed. The first group of output signals carries, for example, the basic parameters of the formation of arcs. These signals, as well as the X and y signals generated by the sampling counters 7, 6, are sent in parallel by a parallel code to high-speed units for calculating the coordinates of the arcs 12, which perform calculations for the circular figures. The output elements of this computing device are digital comparators that form two kinds of signals corresponding to circular shapes having radii different from the thickness of the circle Dg. At the same time, when synthesizing signals, they are applied to the low-voltage modulator, they will form an image of sectors or zone signals outside sectors, respectively. These signals are provided to imaging device 14. The vector coordinate calculation units operate in accordance with the selected calculation algorithm. In this case, two types of signals are also formed at their outputs, corresponding to two similar oblique displacement figures. The imaging unit 14 generates a variety of combinations of input signals, which corresponds to the formation of complex images. The choice of one or another image is carried out in the usual way-by the encoding unit 16, the control inputs of which are supplied with signals taken from the outputs of the decoder 15. The information is encoded by color, brightness, flicker, etc. formed within the zone, is also carried out with the help of coding block 16. Thus, in the process of display, when moving from one zone to another on one raster line, the address of the memory cells automatically changes, and, consequently, the main parameters change. In this case, the form of the synthesized image changes from zone to zone, and, consequently, the repeated use of blocks 12, 13, 8, 14, 15, 16, the use of new elements — computing devices, memory, decryption, encoding and formatting — is advantageous distinguishes the proposed device from. razrazheniya information from the specified prototype, since this greatly expands the functionality, improves the quality of the generated images and simplifies the device. The invention The device for displaying information on a television indicator screen, containing an input unit connected to an input signal storage unit connected to an output unit and a basic parameter calculating unit, a control pulse generator connected to vertical and horizontal sampling counters connected to a character generator, characterized in that, in order to improve the quality of the display, a block of basic parameters is inserted into it, connected to a block for calculating the main parameters The ditch, the counters of the formation of the address by the coordinates X and Y, connected to the memory block of the main parameters and, respectively, to the counters horizontally {$ and vertical sampling, successively co. unified units for calculating the coordinates of arcs and vectors, connected to horizontal and vertical sampling counters and the basic parameters memory block, an imaging unit connected to the character generator and blocks for calculating the coordinates of arcs and vectors, a decoder podklyuchenny to the main parameters memory block to the block coding coupled to an imaging device and a television indicator. Sources of information taken into account in the examination; 1. Authors certificate of the USSR "g 491967, cl. a 06 K 15/20, 02.01.74. 2.Drabkin R.I. Formation of alphanumeric and graphic information on a television screen in the book. Television methods and devices displaying information under the head, Krivs aeeva MI. M., Sov.radio 1975, p. 66-74. vnfuxemofi / m. m. m, a ; / t AT jnJL mf my r