DE2029628B2 - ARRANGEMENT FOR THE CONTROL OF SCREEN DEVICES FOR THE DISPLAY OF CHARACTERS - Google Patents

Description

The invention relates to an arrangement of the type characterized in the preamble of claim 1.

Screen devices are known in which the display of characters on the screen is like a matrix Coordinate network. Characters can be either as a grid of points or from individual vector-like Character segments are composed, the size of a matrix element being the resolution of the Character determined. So is z. B. in US Pat. No. 3,334,304 of the display of characters on the screen a rectangular coordinate matrix is used. The size of this coordinate matrix is limited and their individual fields are the same size. A larger resolution of the character to be displayed could be nor- 4s can sometimes be achieved by enlarging the character matrix, which, however, requires additional circuits, so-called flicker problems (flickering) and additional storage capacity. When the video information is buffered in a circular buffer, the growth of a character matrix would be 7 x 7 units to 10 · 10 units require more than double the memory requirements for the display device.

From British patent specification 11 08 401 an arrangement for controlling display devices for the display of characters by means of step-by-step beam deflection within a character grid field using binary, digitally feedable X and V position registers, each with a downstream decoder for generating an analog deflection voltage in directions perpendicular to each other known. In this system, however, only an equidistant beam deflection is used to generate a character grid. Here, too, an increase in the character resolution would result in an increase in the storage space for the display device.

It is therefore the object of the invention to provide an arrangement as characterized in the preamble of claim 1 Kind to provide, which an increase of the character resolution without additional Schaltkre.se and made possible at no additional cost.

This object is achieved according to the invention in an advantageous manner by the in the characterizing part of the Claim 1 specified measures solved.

Advantageous developments of the invention are the characterizing part of the subclaims to be taken

An embodiment of the invention is shown in the drawings and will be described in more detail below described. It shows

1 shows a block diagram of the invention,

Fig. 2a shows a dual-weighted decoder shown in Fis 1 is shown in block form,

FIG. 2b shows a non-linear weighted decoder shown in FIG. 1 is shown in block form,

3a shows a character which has been generated in accordance with a conventional addressable grid matrix

3b and 3c characters corresponding to the addressable matrix of the present invention.

In Fig. 1 it is shown how binary coded signals from a data source such as. B. a central processing unit 11 via the input lines 21 and 23 to an X input register 25 and Y input register 27 are given. A six-bit Dalen byte is used for each character clock, three bits for the horizontal and three bits for the vertical deflection. The exemplary embodiment of the invention works with an 8 × 8 character matrix which can be represented with three bits for each coordinate, each signal consisting of three bits designating the end point of a vector. Due to a signal transmission on the line 29 from the timer and control circuit 31 , the content of the X and Y input registers is transmitted via pairs of lines with the designations Xi, XX * 3 and Vl, YX V3, Xi and Vl being the rightmost ones Denote bits. This transfer takes place in the X-position register 33 and the V-position register 35. The embodiment described operates in a two-ended push-pull configuration so that each binary determination uses separate lines to represent the one and the zero state. The X and V position registers 33 and 35 contain bidirectional counters or registers, the content of which is increased or decreased in accordance with the input signals applied by the associated input register. A + X signal on the line 34 increases the content of the position register 33 by one, a - X signal on the line 36 decreases the counter by one. Since the present invention is only concerned with character generation, the initial setting for each character has been omitted as unnecessary for an understanding of the present invention. For the initial setting of the beam for the purpose of character generation, however, either a separate deflection coil can be used or the X and V position registers 33 and 35 can be made so large that they can accommodate both the character position and the deflection signals of the individual clock.

On the basis of a transmission signal from the timer and control circuit 31 on the line 37, the contents of the X and V position registers 33 and 35 are transmitted via the lines 39 and 41 to the associated decoders 43 and 45, respectively. In the following in more detail

described horizontal decoder 43 is a conventional dual-weighted linear decoder, in which uniform sirom steps are generated for each positive or negative signal, whichever is applied to the X position register 33. The vertical decoder 45 of the embodiment is a p. non-linear decoder in which the digital addresses after decoding have uneven sirom steps and so a higher resolution in the upper, lower and middle range and a lower resolution in the non-critical intermediate areas, which is described in more detail below will. Due to a control signal on the line

46 become the cumulative X signals on the lines

47 and 49 are transferred from the horizontal linear decoder 43 to the buffer transistors 51 and 53, respectively. The buffer transistors 51 and 53 separate the decoder output of the respective deflection driving circuits 55 and 57. The Ausgaugssignal the deflection driving circuits 55 and 57 of Horizontaljoches the cathode ray tube 61 is applied to the winding 59th In the same way, the output signal of the vertical decoder 45 is passed on the lines 60 and 62 via associated buffer transistors 63 and 65 to the corresponding deflection drivers 67 _2S and 69 and from there to the winding 71 of the vertical yoke of the cathode ray tube 61.

_W When the single horizontal and vertical deflection signals to the accompanying Jockwicklungen given in the above-described 59 or 71, the grating 73 is held not locked by the intensity control circuit 75 miles. Intensity controls with which the beam of a cathode tube can be maintained in the unlocked state during the character generation are well known, χ-, In a conventional method, however, an additional bit is kept in the end point data for information on the intensity control.

In FIG. 2a, details of the horizontal linear decoding shown as block 43 in FIG. 1 are shown schematically in block form. The two-way decoder is operated with three bits ranging from the lowest bit X 1 to bits X 2 and X 3. Since the decoder operates in push-pull mode, a latch register comprising latch circuits 81, 83 and 85 is used. Each stage provides output signals for binary one and zero, which in turn are routed to dual weighted resistors 87, 89 and 91 as well as 87 ', 89' and 9t '. Interlock circuits are generally known components in such a data processing system and differ from flip-flops or triggers only with regard to the time for the reset. The values AR, 2R and R only refer to the dual valency. The actual values will vary depending on the deflection system used, the character size, etc., and are merely well known design considerations. The output signals on lines 47 and 49 represent the cumulative horizontal deflection signals and are fed to the lines shown in FIG. Buffer transistors 51 and 53 shown in FIG. Corresponding to the illustration of the grid arrangements in FIG. 3, the horizontal decoders provide smooth horizontal sweeping steps for each change in the input signal. Since the characters or Zeichenseg- r _v s elements can be produced either from left to right or right depending leftward from the Zeichenkonfiguralion, said the decoder 43 to the output signal Voi-.i X-position register 33 (F ι g. I) that can be increased or decreased in the individual steps described above.

The non-linear vertical decoder 45 used in the embodiment of the invention is shown schematically in block form in FIG. 2b shown. The three-bit coded signals for each character segment are sent to the corresponding locking registers 93, 95 or 97, the individual outputs of which are connected to the resistors 101, 103 and 105 as well as 10Γ, 103 ' and 105' . In contrast to the horizontal deflection, the vertical decoder stages are weighted in a ratio of 1: 3: 5 rather than binary. So have z. B. the rightmost bit of decoding 45 the designation 4R, the next bit further to the left the designation 4/3 /? and the leftmost bit of these three bits is denoted 4/5 /?. The relative ratio of the currents for the eight possible input combinations to the decoder is shown in the table below in decreasing binary steps, with the tabulated coded values corresponding to those in FIGS. 3b and 3c correspond.

Tabel

V3 V2 Vt 1 1 1 1 2 '/ 4 1 1 1 0 2 1 1 0 1 11/2 I. 1 0 0 P / 4 1 0 1 1 I 1 0 1 0 i / 4 I. 0 0 1 '/ 4 1 0 0 0 0

The values for the currents given in the table above are relative, since the actual values are again depend on various design aspects of the respective cathode ray tube device. The output signals from the non-linear decoder 45 are supplied to the Vertical winding 71 of the magnet yoke applied.

In Fig. 3 several characters are shown, including a character that was generated by a conventional rectangular grid and two characters that were generated according to the principle of the invention. All characters are generated on an 8 x 8 matrix. In FIG. 3a, the number 5 is shown on an 8 × 8 coordinate matrix in such a way that eight segments represent the greatest possible resolution that can be achieved with a word of 3 × 3 bits. The number 5 was chosen to exemplify the problems common with conventional coordinate grid matrices. As shown by the number 5 and in particular by the normally curved middle part and lower part of the number, the limited release provides a very poor image quality, so that the number "5" cannot be easily distinguished from the letter "S" . In addition, from a purely human point of view, the graphic image of this sign is undesirable. A traditional method of improving image quality is to increase the resolution of the available grid from 8-8 to a higher number, depending on the level of resolution desired. However, this method requires a larger word size and the whole system including the input registers, position registers, decoders, buffers and also the data bytes

The transmitting data processing system must necessarily be bigger in order to get the bigger word adapt, so that this solution is impractical from an economic point of view.

The present invention offers a more practical solution to this problem. The representations in FIG. 3 should not be an exact representation of the character size, but the problem on an enlarged scale mark. However, the relative proportions are the same as those produced by the present process Sign. In the F i g. 3b and 3c are different ones generated in accordance with the inventive concept in an 8 × 8 matrix Characters shown. The upper matrix lines (111, 110), the lower matrix lines (000, 001) each have areas of fine resolution and show that one Series of fine lines of resolution also run through the central part (010, 011, 100, 101). Both the middle one Lower part (001 to 010) and the middle upper part (101 to

110) provide a relatively rough one in this area Resolution. However, as shown in FIGS. 3b and 3c zi As can be seen, the coarse resolution in this area does not present a problem, but is exacerbated by the aesthetic one Standpoint on the appearance of the sign. The corresponding vertical addresses of each deflection unit are shown in the f i g. 3b and 3c, and the image quality is significantly higher than that of eini conventional square address matrix

ίο ren quality, as shown in Fig.3a. If di ( improved character quality is not readily apparent from the enlarged views of FIGS. 3 emerges, se it becomes all the more clear in an image display system in which the actual size is up to 960 characters be displayed on a cathode ray tube screen of approximately 36 cm. The invention provides a « improved image quality with only minimal changes to the conventional square grid matrix.

For this purpose 2 sheets of drawings

Claims (3)

20 29 claims: 1. Arrangement for controlling display devices for the display of characters by means of step-by-step beam deflection within a character grid field using binary digital feedable X and V position registers each with a downstream decoder for generating an analog deflection voltage in mutually perpendicular directions, characterized in that the grid deflection steps at least one decoder in association with the binary values are not all equidistant. 2. Arrangement according to claim 1, characterized in that in the decoder (45) which does not generate all equidis'.anten raster deflection steps, locking circuits (93, 95, 97) are provided for the individual binary values, which resistors (101, 103, 105; 101 ', 103', 105 ') are connected downstream, which are weighted in the ratio 4: 4/3: 4/5. 3. Arrangement according to claim 1, characterized in that the raster deflection steps of the decoder (45) for the vertical deflection as a function of the step-by-step beam deflection within a Character grid are not equidistant.