DE2429139C3 - Interpolation arrangement for filling in the diagonally opposite empty corners of dot matrix characters - Google Patents

Description

The invention relates to an interpolation arrangement for filling in the diagonally opposite one empty corners at transitions from horizontal to vertical drawing parts formed by matrix points of dot matrix characters which are displayed on a screen in interlaced field processes, Each matrix point consists of two superimposed field segments.

One shortcoming of the dot matrix characters is that, though the vertical and horizontal lines over the full width and height of an element can be drawn, the diagonal parts of the characters have roughly jagged edges and their middle Width only 1 / Vl times the average width of the horizontal and vertical strokes (assuming the elements are square) is what leads to a reduction in brightness of around 30%. This Marigell is visually noticeable.

From US-PS 3573789 it is known to eliminate this deficiency by an integration process, with the quarter of the elements on each side facing each other in the corners of a diagonal part. Such a method is possible because each element is actually consists of segments of two scan lines; a virrtelelement is transformed from an impulse into only one Line and filled in by half the duration of a pulse corresponding to a complete segment; this duration is called the point period. The known interpolation methods are on line scan reproductions as used on data display devices.

The invention is based on the object of specifying a device which, when displayed, is interleaved with Fields can be used, which makes it possible

“5 Hch, improved dot matrix characters on monitors and to map receivers operating to broadcast television standards.

The invention is characterized in that a first circuit for recognizing such Transitions to which the television signal is fed and which contains the three delay devices that make up the TV signal by one matrix point period, one line period or one line period plus one Delay matrix period and which further includes a switching network which combines the output signals c of the delay devices, and by a second Circuit that, depending on the direction of transition, half field segments into the lines of the ersien Field and in the one line delayed period Lines of the second field fade in at the transition points.

As exemplary embodiments of the invention, two forms of embodiment are shown below on the basis of Drawings that show:

Fig. 1a shows a letter "S" in a 7x5 matrix,

Fig. 1b the same letter with a line period delayed odd lines and with interpolated quarter elements that improve are added to the drawing image,

Fig. 2a is a right diagonal (the top right runs) during an even field,

Fig. Ibcinc right diagonal during an odd one Field,

3a shows a left diagonal during an even Field,

Figure 3b is a left diagonal during an odd one Field,

4 is a block diagram of a first embodiment the invention,

Fig. 5 is a block diagram of a second embodiment the invention.

In FIGS. 1 a and 1 b, the strong lines indicate the point clusters which are divided into field segments by horizontally running thinner lines which belong to an even-numbered field (A) and an odd-numbered field (H) , respectively. Fig. Ib shows that the character is not distorted.

if in the original signal (Fig. la) there are clie / i lines the /! lines come in each element, d. H. above the / l-lines, if the ß-lines by one line be delayed; the character is only half the line spacing down in a field postponed.

In Fig. Ib the quarter elements (= half field segments), which are shown hatched are required to improve the reproduction of the diagonal parts. The quarter elements 10 are for example opposite each other across the corner in a right diagonal, while the quarter elements Il stand in a left diagonal with their corners facing each other.

A right diagonal according to FIG. Ib is examined in more detail in FIGS. 2a and 2b. Four field segments defining the diagonal are denoted by I to 4. The segments that appear are hatched, and the quarter elements to be added are cross-hatched. The following relative delays have been made:
Segment 1: not delayed;
Segment 2: delayed by the dot period;
Segment 3: delayed by the line period;
Segment 4: around the line period

plus the point period delayed.

You can also see that the following links define a right diagonal:
Segment 1: no pulse;
Segment 2: pulse present;
Segment 3: pulse present;
Segment 4: no pulse.

Correspondingly, according to FIGS. 3a and 3b, a left diagonal is defined by:
Segment 1: pulse present;
Segment 2: no pulse;
Segment 3: no pulse;
Segment 4: pulse present.

Furthermore, according to FIGS. 2a and 2b, the addition of a quarter element is for the display of a right diagonal in segment 1 (the real-time element) in a / 1 field and in segment 4 in a / J half image necessary. According to FIGS. 3a and 3b, a quarter element is used for the display of a left diagonal required in segments 2 and 3.

A circuit which meets the above requirements is shown in FIG. The signals for the segments T to i, which are defined above, run on lines 1 to 4, and the corresponding inverted signals, AND gates 15 and 16 show the left and d'e, respectively, on lines I to 4 right diagonal according to the links above. Since the effects required in the fields / I and B differ, three changeover switches 12, 13 and 14 are used and switched synchronously with the field frequency.

First of all, Fig. 2a, field A of a right diagonal should be considered, for which a quarter point in the first half segment of segment 1 must be switched on. According to Fig. 4, this requirement is met by the output signal of stage 16 (right diagonal), which triggers an AND gate 17, which passes a clock square-wave signal whose period is the dot period and which is true during the first half of the period. The quarter point pulse thus generated is superimposed on the main signal by an OR gate 18. A one-point delay 19 is required in the trajectory of the main signal for a reason explained below. A further one-point delay 20 between the switch 14 and the AND element 17 compensates for the effect of the delay 19.

Fig. 2b shows that in field ß a right diagonal a quarter element in the last half of the segment of segment 4 must be added. In addition

ίο switches the AND element 16 to an AND element 21 the switch 13 for field ß so that the inverted clock signal can pass through, the is true in the last half of a point period. Between the switch 13 and the AND gate 21

There is no delay, but switch 12 selects now the output of the one-line delay 22 (signal 3), and the main signal at the OR gate 18 has a total delay of one line period plus one dot period; the signal from the AND

ao member 21 therefore sets the quarter point, as required in element 4.

The preconditions for a left agonal can be briefly summarized as follows:
Field A, Fig. 3a: AND gate 15 switches over

5 the switch 13 the AND gate 21 through, whereby a quarter point in the last half of the segment 2 is set because only delay 19 is effective in the main path.

Field ö, Fig. 3b: AND gate 16 switches through the switch 14, the AND gate 17, whereby a quarter point is placed in the first half of segment 3 because the delays in the main path 22 and 19 lie, but delay 20 cancels the effect of delay 19.

It can be seen that in field A the AND stages 15 and 16 cause a quarter point in the first and the second half of a segment, while in field B the AND gates 15 and 16 respectively cause a quarter point in the second and the first Cause half; therefore switches 13 and 14 are required. These switches can be omitted if the switching takes place on the input side of the detector AND elements, whereby in field A the AND elements 15 and 16 are detectors for the left and right diagonal, respectively, while in field B the AND elements 15 and 16 detectors for the right and left diagonal, respectively. It turns out that this is associated with a simplification insofar as the switch 12 and the delay 19 are no longer required. In FIG. 5 this circuit is shown with only two switches 23 and 24. The circuit shows that the following input signals lead to AND gates 15 and 16:
UMD-Jlicd 15, field A:

1 2 3 4 = left diagonal;
AND-GJied 15, field B:
12 3 4 = right diagonal;
AND-GJied 16, field A:
12 3 4 = right diagonal;

AND gate 16, field B:
12 3 4 = left diagonal.

One of the outward point advances. the delay 25, which (as in FIG. 4) is used to generate the input variables for the detector AND elements is, and the associated switch 23 now also take over the function of switch 12 and the delay 19 from FIG. 4.

For this purpose 2 sheets of drawings

Claims (4)

Claims; 1. Interpolation arrangement for filling in the diagonally opposite empty corners Transitions from horizontal to vertical character parts formed by matrix points of Dot matrix characters displayed on a screen in an interlaced field where each matrix point consists of two superimposed field segments, characterized by a first circuit for detecting such transitions, which the Television signal and the three delay devices (z. B. 22) that includes the TV signal by one matrix point period, one line period or one line period plus delay a matrix period and which further includes a switching network (15,16) which the output signals of the delay devices (e.g. 20) and linked by a second circuit (17, 18,21), which, depending on the direction of the transition, half field segments in the lines of the first field and in the lines of the second field delayed by one line period fade in at the transition points. 2. Interpolation arrangement according to claim I, characterized in that the switching network is off two AND gates (15,16), which complement each other, the television signal and the Output signals of the three delay devices, partly directly, partly inverted and their Atiagangssignale the Specify the direction of the transition from horizontal to vertical and that of the second circuit (17, 18, 21) are supplied. 3. Interpolation arrangement according to claim 2, characterized in that changeover switch (13, 14) are provided to which the output signals of the AND gates (15,16) are fed, and the are switched when the field is changed and the output signals of the AND gates (15, 16) apply to the second circuit (17, 18, 21) in different ways. 4. Interpolation arrangement according to claim 2, characterized in that changeover switch (23, 24) provided in front of the inputs of the delay devices (25 etc.) for a matrix point period that are switched when the field changes and alternately the undelayed and the television signal delayed by one line period to the delay means for switch on a matrix point period.