FR2757000A1 - Synchronisation signal generation for cathode ray tube display correction - Google Patents

Abstract

The sawtooth sweep correction method involves generating horizontal and vertical waveform signals for display tube synchronisation. The synchronisation signals have added corrections for the display screen and for the tube geometry. The first correction made to compensate for the display screen, and the second correction for the tube geometry, are preferably carried out separately, and can include both East/West movement and focus. The vertical signal may be adapted for geometry correction and the horizontal signal is then used for display correction. Alternatively the horizontal signal may be used for geometry correction and the vertical signal can be used for display correction.

Description

METHOD FOR GENERATING SCANNING SIGNALS
FOR CATHODIC TUBE RECEIVERS
The present invention relates to a method for generating scanning signals for cathode ray tube receivers. It finds its application in the field of monitors and television receivers.

 In a television receiver, the images are formed on a substantially flat luminescent screen which emits light when struck by an electron beam. This electron beam is emitted by an electron gun placed behind the cathode ray tube of the receiver. Each image is obtained by scanning the point of impact of the beam on the screen in a succession of horizontal lines from left to right and from top to bottom of the screen. This point of impact corresponds to the spot on the screen.

 The angular deflection of the electron beam is carried out by deflection coils which generate horizontal and vertical magnetic fields. The section of the electron beam which corresponds to the focus is adjusted by electrostatic lenses.

Given the non-linearity of the characteristic of the deflection coils and the geometry of the screen, the scanning signals require corrections to obtain an image without distortion on the screen. Most of these corrections are made by inserting reverse distortions into the scanning signals.

There are different types of correction related to the geometry of the cathode ray tube:
- East / West correction allows to correct what is called cushion deformation. This deformation results in the fact that the length swept by the spot on the screen is not the same depending on the altitude of the line scanned. In practice, the length traveled by the spot on the lower and upper lines is greater than for the middle lines. This variation in length is in fact continuous so that the image has on its edges profiles in the form of a parabola. This phenomenon is due to the application, on the horizontal deflection coils, of identical signals whatever the line scanned. To remedy this phenomenon, an East / West correction is carried out which consists in modulating the horizontal scanning signal by a signal in the form of a parabola;
- the correction in S makes it possible to correct the nonuniformity of the spacing between the lines. Indeed, since the cathode of the cathode ray tube is very close to the screen, there is notably a larger path between the cathode and the screen for the highest and lowest lines of the screen than for the midlines. Consequently, for the same vertical scanning angle, the path traveled being greater, the deflection of the spot is greater. The correction in
S consists in adding an S-shaped signal to the vertical scanning signal;
- the focus correction makes it possible to adjust the section of the electron beam as a function of the altitude of the line scanned. This correction is applied to electrostatic lenses of the cathode ray tube; and
- the East / West asymmetry correction, allows to refine the East / West correction. This correction consists in acting on the phase of the synchronization signals.

 Although these last two corrections are not made on the scanning signals, they are nevertheless calculated on the basis of these signals.

 In addition to these corrections, there are adaptation corrections linked to defects in the cathode ray tube (non-uniform magnetic field, edge effects, etc.) or in the circuit for generating the scanning signals (imprecision of the components, delay in switching transistors. , ...).

 Finally, it is also necessary to adapt the scanning signals to the chosen display mode, that is to say that the scanning signals must be modified to take account of the size and position of the luminance signal. Indeed, the image which is represented by a signal called luminance signal, does not occupy the whole of the sawtooth of the horizontal and vertical scanning signals. All these corrections are applied in the method described in FIGS. 1A to 1D.

 FIGS. 1A to 1D illustrate a known method implemented in a cathode ray tube for generating vertical and horizontal scanning signals.

FIG. 1A represents the corrections applied to a vertical scanning signal VST (t). The signal
VST (t) is produced by a sawtooth generation circuit from a vertical synchronization signal VSYNC (t). In practice, this circuit is an oscillator locked on the synchronization signal.
VSYNC (t). The signal VST (t) then undergoes a correction step in S, during which a signal S (t) in the form of S is generated from the signal VST (t) then added to the signal VST (t). This step makes it possible to correct the signal VST (t) as a function of the geometry of the tube. As a rule, this S-correction is made directly in the sawtooth generation circuit. The resulting signal is then modified to take into account the defects of the cathode ray tube and the display mode chosen. In practice, the slope of the sawtooth of the signal VST (t) is modified by multiplying it by a coefficient Vamp and an offset value Vdc is also added to the sawtooth signal. The coefficient Vamp modifies the slope of the sum signal VST (t) + S (t) while the parameter Vdc shifts it in amplitude. A corrected vertical scanning signal VSTCorr (t) is then obtained. This corrected signal is then applied to the vertical deflection coils of the cathode ray tube.

Furthermore, an East / West correction signal EWCorr (t) is generated from the signal VSTCorr (t) to be modulated with the horizontal scanning signal. In practice, a parabola is generated at order 2 from the signal VsTcorr (t) and then the amplitude of this parabola is adjusted with a coefficient EW ,, pr and an offset value EWdC is added to the resulting parabola. The EWamp and EWdC parameters help to adjust the position and amplitude of the EWcorr (t) parabolic signal
Likewise, a first correction signal for the cross section of the electron beam VfoccOrr (t) is produced from the corrected signal VSTcorr (t) to be applied to electrostatic lenses intended for adjusting the cross section of the electron beam. In practice, we generate a parabola Vfoc (t) which we multiply by a coefficient Vfocamp and to which we add an offset value Vfosdc. The parameters Vfocamp and Vfocdc also help to adjust the position and amplitude of the parabolic signal Vfoccorr (t).

FIG. 1B represents the time diagram of the signals important for the correction in S. This figure represents:
- the vertical scanning signal VST (t);
- the signal S (t) which is added to the vertical scanning signal VST (t) during the correction in
S; and
- the luminance signal L (t) indicating the position and the size of the image with respect to the scanning signal VST (t); this signal actually comprises a plurality of elementary pulses each associated with a line.

It is noted that the duration of the pulse of the luminance signal L (t) is less than the period T of the signal
VST (t). On the other hand, the period of the signal S (t) is equal to the period of the signal VST (t). The settings
Vamp and Vdc allow you to adjust the slope and position of the VST (t) + S (t) signal to obtain a full screen, centered image. In reality, it is necessary to add a correction at C (not shown) to re-center the signal S (t) with respect to the signal L (t) and thus eliminate the non-uniformity of the spacing of the lines on the screen.

 FIG. 1C represents the corrections made to the horizontal scanning signal HST (t). This signal comes from a sawtooth generation circuit whose input receives a horizontal synchronization signal HSYNC (t). The signal first undergoes adaptation corrections linked to the tube faults and to the display mode, then is modulated by the East / West correction signal EWCorr (t). These corrections are symbolized in the figure by the Hamp coefficient and the offset value Hdc. The resulting horizontal scanning signal HSTCorr (t) is then applied to the horizontal deflection coils of the cathode ray tube. The unmodulated signal is also used to generate a Hfoc (t) parabolic signal. This signal is then adjusted in amplitude by an Hfoc coefficient to produce a second focus correction signal HfoccOrr (t).

 Finally, FIG. 1D represents the time diagram of the horizontal scanning signal HST (t) as well as that of the luminance signal L (t). The signal pulse L (t) shown in this figure corresponds to the elementary pulse associated with each line. The Field and Hdc parameters will act on the HST (t) signal so that the resulting signal is suitably positioned and sized with respect to the L (t) signal in order to obtain, after modulation, a line adapted to the dimensions of the screen.

This type of process has three major drawbacks
10) At each change of display mode, that is to say at each modification of the signal L (t), it is necessary to readjust the parameters Vamp and Vdc although the signal L (t) is perfectly known for each mode d 'display; this readjustment of the parameters Vamp and Vdc then impose to readjust all the other process correction parameters; therefore a complete set of parameters is required per display mode;
20) the signal S (t) of the correction in S is applied to the entire sawtooth of the signal
VST (t); this correction in S is therefore applied by supposing that the image is present throughout the sawtooth of the signal VST (t); however the reduced size and the decentralization of the signal L (t) compared to the rising part of the signal VST (t) introduce errors errl and err2 (figure 1B) which require additional corrections (correction in C) to refocus the signal S (t) with respect to the signal L (t); these errors also have repercussions on the other corrections, which makes it essential to add additional corrections (trapezoidal correction, etc.);
30) the pooling of the corrections linked to the defects of the cathode ray tube with the corrections linked to the display mode induces a dependence between the correction S and the parameters Vamp and v Vdc; indeed, the errors err1 and err2 introduced by the correction in S modify the amplitude of the vertical sawtooth and influence the value of the parameters Vamp and Vdc; the procedure for adjusting the cathode ray tube is therefore very difficult to develop since it is necessary to master the interdependence of the parameters of the various corrections;
To overcome these drawbacks, the invention proposes on the one hand to dissociate the parameters linked to the tube defects and the parameters linked to the display mode and on the other hand to carry out the corrections linked to the tube defects after the correction of the display mode.

Also, the subject of the invention is a method intended to be implemented in a cathode-ray tube receiver, for generating from two signals of horizontal synchronization and vertical synchronization respectively, two sawtooth signals, respectively of horizontal scanning and vertical scanning signals, the horizontal scanning and vertical scanning signals having undergone adaptation corrections linked for a part of them to the geometry and / or to defects of the cathode ray tube concerned, and for another part to the mode display chosen,
characterized in that the adaptation corrections linked to the geometry and / or to defects of the cathode ray tube concerned are carried out separately from the corrections linked to the chosen display mode,
and in that the adjustment corrections linked to the geometry and / or to defects of the cathode ray tube concerned are made after the corrections linked to the chosen display mode.

Other characteristics and advantages of the invention will appear on reading the detailed description which follows and which is given with reference to the appended drawings in which
- Figures 1A to 1D, already described, illustrate a known method implemented in a cathode ray tube to generate vertical and horizontal scanning signals;
- Figures 2A to 2C are the counterparts of Figures 1A to 1C to illustrate the method of the invention; and
- Figures 3A and 3B are time diagrams of the vertical and horizontal synchronization signals.

 The method chosen for the invention consists in dissociating the correction parameters specific to the display mode from the correction parameters linked to the geometry and to the defects of the cathode ray tube, and to carrying out the corrections linked to the geometry or to the defects of the tube after display mode corrections. Thus, all the corrections related to the geometry of the tube are made on a signal corrected with respect to the display mode.

 FIGS. 2A to 2C illustrate the method of the invention. The generation of the vertical scanning signal is detailed in Figure 2A. A sawtooth signal VST (t) is produced from the vertical synchronization signal VSYNC (t). The signal VST (t) is then shifted in amplitude by a parameter VMT and then multiplied by a coefficient Vamp. We then obtain a signal y (t). The two correction parameters VMX and VMamp relate only to the display mode. The amplitude offset of the sawtooth is in fact equivalent to a time offset of the sawtooth. In the following description, the parameters designating pseudo-time shifts are indicated by the letter n. In the method of the invention, this time shift of the signal VST (t) makes it possible to position the sawtooth properly with respect to the luminance signal and thus makes it possible to eliminate the addition of additional corrections (correction in C, ...) during the correction in S. In practice, a pair of parameters (VOMI, Vamp) is calculated beforehand for each display mode and all of these pairs are preloaded in the circuit implementing the method. At each change of standard, it will suffice to load the parameters VMt and VMamp of the new standard. This is why, this method is more particularly intended to be implemented in multi-mode monitors.

 All the corrections related to the geometry and the defects of the tube are then carried out on the basis of the signal y (t).

To obtain a corrected vertical scanning signal, an S-correction is first performed and parameters are introduced to correct the defects in the cathode ray tube. First of all, an amplitude offset S7 is introduced into the signal y (t) which is equivalent to a time offset of the sawtooth y (t). An S-shaped signal S (t) is then generated from the shifted signal and then multiplied by the Samp coefficient to form the Scorr (t) signal. The parameters St and Samp allow respectively to adjust the position and the amplitude of the signal S (t) compared to the signal y (t). Then the signals y (t) and
Scorr (t) are added and the signal obtained is then adjusted in amplitude and position by parameters, respectively VSTamp and VSTdc. The VSTdC parameter makes it possible in particular to compensate for any offset of the magnetic field produced by the vertical deflection coils. The VST coefficient makes it possible to adjust the gain of the amplifier placed at the output of the vertical scanning circuit and to correct the amplitude of the magnetic field produced by the vertical deflection coils. Finally, a corrected vertical scanning signal VSTCorr (t) is obtained. The large number of parameters used for adjusting the cathode ray tube does not constitute a drawback since these parameters are now independent of the parameters of the display mode. Furthermore, these parameters are adjusted once and for all at the time of the factory setting of the monitor for a given mode and then remain unchanged regardless of the display mode used.

The same approach is used to produce the East / West correction signal EWcorr (t). First of all, an amplitude shift EWT is introduced into the signal y (t) which is equivalent to a time shift of the sawtooth y (t). A parabolic signal EW (t) is then generated from the offset signal. The EWT parameter is used to adjust the position of the EW (t) parabolic signal with respect to time. Then the signal
EW (t) is adjusted in amplitude by the coefficient EWamp.

An EWdC parameter is then added to the resulting signal to adjust the position in amplitude of the East / West correction signal EWcorr (t). Thus, according to the method of the invention, the parabolic signal EW (t) is produced from a linear signal y (t). In the prior art method, the parabolic signal is generated from a non-linear signal VST (t) + S (t), this results in introducing distortions in the periodic signal EW (t ).

 Furthermore, to generate the first EWCorr (t) focus correction signal, the same approach is applied. First of all, an amplitude offset Vfoct is introduced into the signal y (t) which is equivalent to a temporal offset of the sawtooth y (t). A parabolic signal Vfoc (t) is then generated from the offset signal. The VfocX parameter is used to adjust the position of the Vfoc (t) parabolic signal with respect to time. Then the signal Vfoc (t) is adjusted in amplitude by the coefficient Vfocamp. We then add a parameter Vfocdc to the resulting signal to adjust the position in amplitude of the focus correction signal VfoccOrr (t). The parameters VfocX, Vfoc ,, p, Vfocdc, EWX, EWamp and EWdc are of course adjusted once and for all at the factory.

FIG. 2B makes it possible to display the period and the position of the signal S (t) relative to the luminance signal L (t). The signal period S (t) is now equal to the duration of the luminance signal pulse.
L (t) and the signal S (t) are canceled at the beginning and at the end of this pulse. All the process equations relating to the correction of the vertical scanning signal are provided in an annex A attached to the present application.

The generation of the horizontal scanning signal is detailed in Figure 2C. A sawtooth signal
HST (t) is first produced from the horizontal synchronization signal HSYNC (t). The HST signal (t) is then shifted in amplitude by an HMT parameter and then multiplied by an HMmp coefficient. These two correction parameters relate only to the display mode. This gives a signal x (t). The HNT offset equivalent to a time offset makes it possible to position the HST signal (t) relative to the luminance signal. The HMamp coefficient makes it possible to adjust the amplitude of the HST signal (t) with respect to the display mode. The signal x (t) is then adjusted in amplitude and position by two parameters, respectively HSTamp and HSTdC. The HSTdC parameter makes it possible in particular to compensate for any offset in the magnetic field produced by the horizontal deflection coils. The HSTamp coefficient makes it possible to adjust the gain of the amplifier placed at the output of the horizontal scanning circuit and to correct the amplitude of the magnetic field produced by the horizontal deflection coils. The resulting signal is then modulated by the East / West correction signal EWCorr (t) and the corrected horizontal scanning signal HSTcorr (t) is then obtained.

 To produce the second focus correction signal, we first introduce into the signal x (t) an amplitude shift HfocT which is equivalent to a time shift of the sawtooth x (t). A parabolic signal Hfoc (t) is generated from the offset signal. The Hfoct parameter is used to adjust the position of the parabolic signal Vfoc (t) with respect to time.

Then the signal Hfoc (t) is adjusted in amplitude by the coefficient Hfoca, p The set of process equations relating to the correction of the horizontal scanning signal are provided in an annex B attached to this application. The HMT, HMamp, HSTamp, HSTdC, Hfoct and Hfoc, mp parameters are also adjusted once and for all at the factory.

Each display mode has its own luminance signal, the temporal characteristics of which are defined with respect to the vertical and horizontal synchronization signals. The temporal characteristics of the luminance signal
L (t) and of the vertical synchronization signal VSYNC (t) are defined in FIG. 3A:
TV is the period of the vertical synchronization signal VSYNC (t);
- T1 is the duration during which the luminance signal L (t) is not zero;
- Tp1 is the duration of the pulse of the vertical synchronization signal VSYNC (t);
- Td1 is the time between the end of the pulse of the signal VSYNC (t) and the start of the pulse of the luminance signal L (t); and
- Tf1 is the duration between the end of the pulse of the luminance signal L (t) and the start of the pulse to follow of the signal VSYNC (t);
From these time characteristics, it is then possible to deduce the value of the parameters specific to the display mode. We thus obtain:
VMamp = TV and VM # = (Tp1 + Td1-Tf1) / 2
T1 TV
Similarly, the time characteristics of an elementary pulse of the luminance signal L (t) and of the vertical synchronization signal VSYNC (t) are defined in FIG. 3B:
- TH is the period of the horizontal synchronization signal HSYNC (t);
- T2 is the duration of an elementary pulse of the luminance signal L (t);
- Tp2 is the duration of the pulse of the horizontal synchronization signal HSYNC (t);
- Td2 is the duration between the end of the pulse of the HSYNC signal (t) and the start of the elementary pulse of the luminance signal L (t); and
- Tf2 is the duration between the end of the elementary pulse of the luminance signal L (t) and the start of the pulse to follow of the signal HSYNC (t);
We then deduce the value of the horizontal correction parameters of the display mode: HMamp = JH and HMT = (Tp2 + Td2 / 2
T2 TH
In conclusion, the method according to the invention has the following advantages:
- The method of the invention requires only one set of parameters relating to the corrections related to the geometry and the defects of the tube; these parameters are determined in a display mode given at the time of the factory setting and then stored in a memory with the display mode correction parameters; the display mode is changed only by changing the four mode correction parameters (VMamp, VMT, HMamp, H);
the procedure for adjusting the parameters is simplified due to the independence of the adjustments of the various corrections; indeed, the setting of the parameters of the VSTamp, VSTdC, Samp, S # parameters is completely independent of the setting of the VMamp VMT parameters;
- the addition of additional corrections to refine the corrections related to the geometry of the tube is no longer justified; and
- Finally, the correction at S is carried out on a signal corrected with respect to the display mode in the same way as the other corrections linked to the geometry of the cathode ray tube;
APPENDIX A vertical correction equations
Tube geometry and defect correction parameters
VSTamp, VSTdc
Samp, ST
EWamp, EWdc, PINamp, PINT, CORNERamp, CORNER #
Vfocamp, VfocX, Vfocdc
Display mode correction parameters VMamp VMT
Variable
We define: y (t) = VMAMp * (VST (t) - VM #) y (t) is the vertical sawtooth corrected according to display mode 1 - Correction of the vertical sawtooth
Correction in S
Scorr (t) = Samp [(y (t) - S #) * (TV / 2 - abs (y (t) - 8T))]
Correct ion of vertical sawtooth with corrections of cathode ray tube defects
VSTcorr (t) = VSTamp * [y (t) + Scorr (t)] + VSTdc 2 - East / West correction
PINcorr (t) = PINamp * (y (t) - PIN #) CORNERcorr (t) = CORNERamp * (y (t) - CORNER) 4
East / West correction with corner corrections
EW (t) = EWamp * [PINcOrr (t) + CORNERcorr (t)) + EWdc 3 - Correction Focus
Vfoc (t) = Vfocamp * (y (t) - Vfoct) + Vfocdc
APPENDIX B horizontal correction equations
Focus correction parameters Hfocamp, Hf oc T
Display mode correction settings
HMamp, HM #
Variable
We define: x (t) = HMamp * (HST (t) x (t) is the horizontal sawtooth corrected according to the display mode
Correction Focus
Hfoc (t) = Hfocamp * (x (t) - Hfoc #)

Claims (3)

 1 - Method intended to be implemented in a cathode-ray tube receiver, for generating from two signals of horizontal synchronization (HSYNC (t)) and vertical synchronization (VSYNC (t)) respectively, two sawtooth signals , horizontal scanning (HSTCorr (t)) and vertical scanning (VSTCorr (t)) respectively, the horizontal scanning (HSTcorr (t)) and vertical scanning (VSTcorr (t)) signals having undergone adjustment corrections partly linked to the geometry and / or faults of the cathode ray tube concerned, and for another part to the chosen display mode,  characterized in that the adaptation corrections linked to the geometry and / or to defects of the cathode ray tube concerned are carried out separately from the corrections linked to the chosen display mode,  and in that the adjustment corrections linked to the geometry and / or to defects of the cathode ray tube concerned are made after the corrections linked to the chosen display mode.  2 - Method according to claim 1, characterized in that the adaptation corrections of the vertical scanning signal related to the geometry and / or to defects of the cathode ray tube concerned comprise a correction in S.  3 - A method according to claim 2 or 3, characterized in that the adaptation corrections of the horizontal scanning signal related to the geometry and / or faults of the cathode ray tube include an East / West correction.