FR2779862A1 - Anti flicker or shimmer deflection control device for cathode ray tube. - Google Patents

Abstract

Delays and advances the start of a trigger signal for a ramp function. The deflection control device (12) for horizontal sweep control of a cathode ray tube (3) at a set frequency includes a section (9) for providing a succession of current ramps to a horizontal deflection system. The current at the start of each ramp is at a negative value, opposed to the positive value at the end of the preceding ramp. There is a section (5) which provides a periodic reference signal corresponding to the sweep frequency, and a unit (7) to trigger each ramp start, according to a predetermined time relationship, with the reference signal. In addition a section is provided for shifting the trigger according to a sequence, twice delayed and twice advanced and so on

Description

ANTI - MOIRED DEVICE FOR A CATHODE TUBE SCREEN

  The present invention relates to the control of cathode ray tube screens, and more particularly the control of screens

  cathode ray tube computers for displaying color images

  their. To display color images, the inside face of a CRT screen has three phosphors of different types, red, green and blue, deposited

  side by side in various patterns. The three light networks

  phores are illuminated by three electron beams very close and deflected together, each of which will strike only phosphors of a single color. A scanning control circuit allows the electron beams to be deflected according to a

succession of horizontal lines.

  In computer screens, shades of gray are conventionally obtained by displaying on the screen an alternation of lit and unlit dots with a sufficiently fine pitch so that the eye can only distinguish uniform lighting. It can happen that this display pitch and the pitch of phosphors of the same color

are close.

  This is illustrated in FIG. 1 in which we have represented

  felt in solid lines a network of phosphors 10,

  corresponding to a small part of the phosphors of the same color

  their of a screen, on which an electron beam forms an alternation of illuminated zones 20 shown in dotted lines and of unlit zones. The shape and size of the phosphors and the illuminated areas are simplified for the sake of clarity. The parts of the phosphors 10 lit by the zones 20 are represented by the hatched zones 30. We then obtain on the screen (for each color) a periodic pattern of lit points, partially lit (area 40) or unlit. It

  For the observer, a moiré effect results.

  It is known to eliminate the moiré effect by shifting the excitation network from one line to another by half a step. Then an illuminated area takes the place of an unlit area and vice versa and the moiré effect disappears. To avoid giving the edge of the displayed images a "jagged" appearance, the lines shifted to the right and shifted to the left are reversed

image out of two.

  FIG. 2 very schematically represents a horizontal scanning control circuit 1 usually used with

  a cathode ray tube 3. Circuit 1 includes a reference circuit

  rence 5 producing a voltage signal V consisting of a series of voltage ramps. The signal V is synchronized in frequency and in phase with the video signal. A comparison circuit 7 compares the voltage V with an adjustable threshold voltage Vt and produces a return signal R when the voltage V is equal to the

threshold voltage Vt.

  A deflection circuit 9 is crossed by a current I. The current I increases between a start of line current and an end of line current with a constant slope. The circuit 9 is connected to the comparison circuit 7 to receive the return signal R. When the circuit 9 receives the return signal R, the intensity which passes through it goes to the opposite value in a constant time (return time). This return time is not useful for

  understanding of the invention, and has not been shown.

  Thus, if the current I has reached a value + i when the circuit 9 receives the signal R, the current I then takes the value -i, then starts to grow again according to the constant slope mentioned above. Current I acts on a deflector 12 and determines the deflection of an electron beam F emitted by a source S towards the screen 3 of the cathode-ray tube. When the current I increases linearly between the values -i and + i, the point of impact of the beam F on

  the screen 3 continuously evolves between a position Ai and a position

  tion A + i. A line is thus displayed on the screen. Means not shown make it possible to adjust the intensity of the beam F to define on the line lit or unlit points. Of

  means, also not shown, make it possible to deflect the beam

  Ceau F vertically, in order to successively describe the lines

of each image.

  FIG. 3A represents a curve corresponding to

  the evolution of a voltage V as a function of time t in the circuit

  reference bake 5 of FIG. 2. The voltage V described from

  periodically a series of slope voltage ramps cons-

  aunt. Each voltage ramp V goes from a zero voltage to a threshold voltage VtR in a time tR. A comparison means such as the circuit 7 of FIG. 2 produces a return signal R each time the voltage V reaches the value VtR. When no moiré correction is made, the signal R produced at time tR is used to trigger the end of a scanning line and

  the start of the next scan line.

  To shift every other line, it has been proposed

  to use every other line a higher voltage threshold VtR + AV

  lower than VtR, and every other line a voltage threshold VtR-AV lower than VtR. However, this simple solution, as we will

  show in relation to FIG. 3B, does not lead to a result

satisfactory condition.

  FIG. 3B represents two curves 11 and 11 ′ cor-

  corresponding to the current I passing through the deflection circuit 9 of FIG. 2, respectively without and with moiré correction. Current I increases in a constant slope between a start of line current and an end of line current. When the end of a line is reached, the current I is reversed and the value

  reversed becomes the start current of the next line.

  Curve 11, in solid lines, corresponds to the change in current I when each line ends at the aforementioned time tR, that is to say when no correction is made. The current I oscillates stably between values -i and + i. A value -i of the current I at the start of the line corresponds, as we have seen in relation to FIG. 2, to a start point

of line determined.

  The curve 11 ', in dotted lines, corresponds to the evolution

  of current I with the aforementioned simple correction.

  The threshold value which determines the end of line L1, that is to say the start of a second line L2, is fixed at VtR + AV. The end of the line L1 corresponds to the instant tR + At o where the voltage V reaches the value VtR + AV. The slope along which the current I evolves being constant, if the current I reaches a value i at the instant tR, it reaches a value i + Ai at the instant tR + At. So the line start current of the second line

  L2 is equal to - (i + Ai). Such a line start current cor-

  corresponds to a line start point shifted to the left by

  relation to the line start point determined by a current -i.

  Then, the threshold value which determines

  mine the end of line L2, i.e. the start of a second line L3. The end of the line L2 corresponds to the instant tR-At when the voltage V reaches the value VtR-AV. However, the current I a

  a value - (i + Ai) at the start of line L2 and reaches a value i-

  3Ai at the end of the line, at time tR-At. Thus, the line start current of the third line L3 is equal to - (i-3Ai). Such a line start current corresponds to a line start point shifted to the right with respect to the start point of

  line determined by a current -i.

  By repeating the process, the line start current of a fourth line L4 will be - (i + 5Ai), and the start current of

  line of a fifth line L5 will be - (i-7Ai).

  We can in particular observe a point M located exac-

  in the middle of each video line. Without a moiré correction device, this point is displayed at the moment when the deflection current passes through 0. With the moiré correction device, at the same time, the current is no longer zero, and its value indicates how the movement will be moved. midpoint of screen M, to the right for a positive value or to the left for a

negative value.

  FIG. 4 very schematically represents the position on a screen of lines (L1, L2, L3, ...) of an image obtained with the correction described above. The midpoint

  M of each line is also shown. The start of a pre-

  1st line L1 is not modified. Current I is equal to - (i + Ai)

  at the start of line L2, which is shifted to the left. The neck-

  rant I equal to - (i-3Ai) at the start of line L3, which is shifted to the right. Current I is equal to - (i + 5Ai) at the start of line L4, which is shifted to the left. It is thus noted that the beginnings of the even lines are gradually shifted to the left and that the beginnings of the odd lines are gradually shifted to the right. End-of-line points are derived from

similar way.

  Although the shifts to the right and to the left have been significantly exaggerated in Figure 4 for reasons of clarity, the drift of the start and end of line positions, and especially the drift of the midpoint M of each line, are visible on the screen and are unacceptable. The simple method described above cannot therefore be used as it is. So we proposed in art

  much more complex processes such as

  full call for servo drives.

  An object of the present invention is to provide a

  horizontal scanning control circuit having a provision

  moire correction sitive not causing drift of

  start and end points of lines on a screen.

  Another object of the present invention is to provide

  such a device which is easy to implement.

  To achieve these and other objects, the pre-

  sente invention provides a device for controlling a deflection device for the horizontal scanning of a tube screen

  cathodic according to a determined scanning frequency, including

  nant: a means for supplying a succession of current ramps to a horizontal deflection system, the current from each start

  ramp being at a negative value opposite the posi-

  tive of the end of the previous ramp, means for providing a periodic reference signal corresponding to the scanning frequency, means for causing the triggering of each start of ramp according to a predetermined time relationship with

  the reference signal, and a means for shifting said trigger

  lying in sequence, twice late then twice in

advance and so on.

  According to one aspect of the present invention, the device

  includes means for inter one image displayed on the other

  green the triggers in advance and the triggers in

delay in said sequence.

  According to one aspect of the present invention, said early and late triggers are chosen to produce

  a shift in the display of the midpoint by two lines

  roughly equal to half the interval between

  the centers of two phosphor elements of the screen.

  The present invention also relates to a method for controlling a deflection device for the horizontal scanning of a cathode ray tube screen according to a determined scanning frequency, comprising: supplying a succession of current ramps to a horizontal deflection system , the current of each start of ramp being at a negative value opposite to the positive value of the end of the previous ramp, supply a periodic reference signal corresponding to the sweep frequency, cause the triggering of each start of ramp according to a relation predetermined time with the reference signal, and shift said trigger in a sequence two

  times early then twice late and so on.

  According to one aspect of the present invention, the method further comprises the step which consists, of an image displayed on the other, in reversing the triggers in advance and the

  late triggers in said sequence.

  According to one aspect of the present invention, said early and late triggers are chosen to produce

  a shift in the display of the midpoint by two lines

  roughly equal to half the interval between

  the centers of two phosphor elements of the screen.

  These and other objects, features and advantages of the present invention will be discussed in detail in

  the following description of particular embodiments

  made without limitation in relation to the attached figures among which:

  FIG. 1 represents a network of lumino-

  screen phores; Figure 2 very schematically shows a horizontal scanning control circuit of a cathode ray tube screen;

  FIG. 3A represents a curve illustrating the function

  operation of a reference circuit to control a scan;

  FIG. 3B represents curves illustrating the function

  operation of a sweep control circuit with and without moiré correction; FIG. 4 represents the display of lines of a screen after correction of moiré using the method described in relation to FIGS. 2, 3A and 3B;

  FIG. 5A represents a curve illustrating the function

  operation of a reference circuit for controlling a scan according to the present invention;

  FIG. 5B represents curves illustrating the function

  operation of a scanning control circuit with and without moiré correction according to the present invention; and figure 6 represents the display of lines of a screen

  after correction of moiré according to the present invention.

  Figure 5A is similar to Figure 3A. FIG. 5A represents a curve corresponding to the evolution of a voltage V as a function of time t in a reference circuit such as circuit 5 in FIG. 2. When no moiré correction is made, the end of a scan line and the start of the line

  next scan are triggered at a time tR, corresponding to

  dant at the instant when the voltage ramp V reaches a voltage of

VtR threshold.

  According to the present invention, the threshold voltage which determines the end of two consecutive lines is increased, then the threshold voltage which determines the end of two consecutive lines is decreased and so on. The value of the threshold voltage VtR is replaced twice in succession by a threshold voltage equal to VtR + AV and the voltage ramp V reaches twice this value in an instant tR + At. Similarly, the value of the threshold voltage VtR is replaced twice in succession by a threshold voltage equal to VtR-AV and the voltage ramp V reaches this value twice in succession at an instant tR-At. Remember that the position of a line start is symmetrical with respect to a

  center line of the screen for the position at the end of the previous line

  toothed. So, if we shift an end of line to the right, we shift

  on the left the beginning of the next line, and vice versa.

  FIG. 5B represents two curves 11 and 13 cor-

  corresponding to the current I passing through the deflection circuit 9 of FIG. 2 respectively without and with moiré correction according to the present invention. The curves 11 in FIGS. 5B and 3B are identical. In curve 11, each line ends in a conventional manner at the aforementioned time tR, the current I oscillates by

  stably between values -i and + i.

  The curve 13, in dotted lines, corresponds to the evolution of the current I when the moiré correction is carried out according to

1 invention.

  The threshold value which determines the end of line L1, that is to say the start of a second line L2, is fixed at VtR + AV. The end of line L1 corresponds to the instant tR + At o where the voltage V reaches the value VtR + AV and the triggering of the start of the current ramp I is thus shifted late by At. Conome as we have seen in In relation to FIG. 3B, the current I reaches a value i + Ai. Thus, the line start current of the second line L2 is equal to - (i + Ai), which corresponds to a line start point shifted to the left relative to the point of

  start of line determined by a current -i.

  The threshold value which determines the end of line L2 is again fixed at VtR + AV. The end of the line L2 corresponds to the instant tR + At o where the voltage V reaches the value VtR + AV, the triggering of the start of the current ramp I is shifted late by At, and we notice that the current I reaches here an i-Ai value. Thus, the line start current of the third line L3 is equal to - (i-Ai), which corresponds to a line start point shifted to the right with respect to the point of

  start of line determined by a current -i.

  The threshold value which determines the end of line L3 is now fixed at VtR-AV. The end of the line L3 corresponds to the instant tR-At o the voltage V reaches the value VtR-AV, the triggering of the start of the current ramp I is shifted in advance by At, and we notice that the current I reaches an i-Ai value. Thus, the line start current of the fourth line L4 is equal to - (i-Ai), which corresponds to a line start point shifted to the right with respect to the start point of

  line determined by a current -i.

  Finally, the threshold value which determines

  mine the end of line L4. The end of line L4 corresponds to the instant tR-At where the voltage V reaches the value VtR-AV, the triggering of the start of the current ramp I is shifted in advance by At and it is noted that the current I reaches a value i + Ai. Thus, the line start current of the fifth line L5 is equal to - (i + Ai), which corresponds to a line start point shifted to the left relative to the start point of

  line determined by a current -i.

  A sixth L6 line will be shifted like the second

line L2, and so on.

  As has just been described, according to a main aspect

  pal of the present invention, the triggering of each start of current ramp is shifted in a sequence, twice in

  late then twice in advance and so on.

  It is noted that, according to the present invention, the values of the end of line current have one or the other of the values i + Ai and i-Ai, and that the values of the start of line current have one or the other of the values (i + Ai) and - (i-Ai). This

  is very schematically illustrated in Figure 6 which represents

  feel the position on a screen of lines (L1, L2, L3, ...) of an image obtained with the moiré correction device according to

the invention.

  Note in Figure 6 by observing the display position of the points M in the middle of the successive lines that the present invention allows a regular shift of the displayed lines. To effectively suppress moiré, the increase in voltage AV is chosen so that it causes an increase in current Ai such that the interval (2Ai) between two successive midpoints M is substantially equal to half the interval separating the centers of two phosphor elements

of the screen.

  Preferably, the advanced lines and the delayed lines are inverted from one image to the other. Thus, means for modifying the threshold voltage Vt into Vt + AV and Vt-AV will be substituted for one another from one image to the other, so that the lines whose start is shifted to the left in an image have a start shifted to the right in the following image, and

and so on.

  The previous description was made in relation to

  a reference circuit 5 and a comparison circuit 7 analog

  gics. The invention can easily be adapted to a control circuit in which the reference circuit and the comparison circuit are both digital. For example, the circuit of

  reference can be a digital counter incremented to a frequency

  much higher than the scanning frequency, reset synchronously in frequency and in phase with the video signal. In this case, the comparison circuit can be digital and make a comparison between the output of the counter and a

  predetermined threshold value. So according to the present invention

  tion, provision will be made for successively setting this threshold value twice at a high value and twice at a

low value.

  On the other hand, the present invention has been described in

  relationship with a cathode ray tube screen with non-display

  laced, but the skilled person will easily adapt the present

  description to an interlaced display. Likewise, the present invention

  tion will be used in the context of conventional horizontal deflection circuits, possibly fitted with scanning correction systems (for example S correction) and in

  which the scan return duration is not zero.

Claims (6)

  1. A device for controlling a deflection device (12) for the horizontal scanning of a cathode-ray tube screen (3) according to a determined scanning frequency, comprising: means (9) for supplying a succession of current ramps to a horizontal deflection system, the current of each start of the ramp being at a negative value opposite to the positive value of the end of the previous ramp,   means (5) for providing a peri-reference signal   dic corresponding to the scanning frequency, means (7) for causing the triggering of each start of the ramp according to a predetermined time relationship with the reference signal, characterized in that it further comprises means for shifting said triggering by a sequence, twice in   late then twice in advance and so on.   2. Device according to claim 1, characterized in that it comprises a means for, from an image displayed on one another, invert the triggers in advance and the   late triggers in said sequence.   3. Device according to claim 1, characterized in that said early and late triggers are chosen to produce an offset of the display of the midpoint of two consecutive lines substantially equal to half the interval   separating the centers of two phosphor elements from the screen.   4. Method for controlling a deflection device for the horizontal scanning of a cathode-ray tube screen according to a determined scanning frequency, consisting of:   provide a succession of current ramps to a system   horizontal deflection teme, the current of each start of the ramp being at a negative value opposite to the positive value of the end of the previous ramp, provide a periodic reference signal corresponding to the sweep frequency, causing the triggering of each start of ramp according to a predetermined time relationship with the reference signal, characterized in that it further comprises the step of shifting said trigger in a sequence two   times early then twice late and so on.   5. Method according to claim 4, characterized in that it consists of an image displayed on the other, to invert early triggers and late triggers in said sequence.   6. Method according to claim 4, characterized in that said early and late triggers are chosen to produce an offset of the display of the midpoint of two consecutive lines substantially equal to half the interval   separating the centers of two phosphors from the screen.