FR2793640A1 - Widescreen television automatic widescreen/square format having command/control blockage mechanism generating predetermined width pulse position signals separate from synchronous signals. - Google Patents

Abstract

The widescreen to normal format automatic television control has a screen (18) , video reception receiver (17) , video receiver blockage (181,182) and blockage control (2-6,9,21-26). The means of command and control have a mechanism generating a pulsed position signal of predetermined width separate from the synchronous signal on the video signal.

Description

TV monitor <B> to </ B> screen <B> 16/9 <B> There </ B> today has more and more TVs including CRT <B> or < The flat screen can offer an image of length and width in a <B> 16/9 ratio. </ B>

When, for one reason or another, the viewer wants to see an image of length and width in a ratio of 4/3, <B> (12/9), </ B> it is reproduced in the center of the screen and it remains, on both sides of the 4/3 image, a sideband <B> 2/9 </ B> in which the screen is not controlled. As a result, the two vertical edges of the 4/3 image are irregular and must be masked.

<B> A </ B> this effect, <B> to </ B> each scan line of the spot, we proceed <B> to </ B> a blocking (blanking) of the pixel of the video signal received from the tuner, which is not sent on the cathode ray tube (we are talking about blanking in the infranoir), to use this example, and this, at the beginning of the line scan, for a duration tl, and at the end of the line scan, during a duration T-t2, where T is the duration of the line scan. Thus, each sideband <B> 2/9 </ B> is slightly expanded to cover the parasitic edges of the useful image 4/3. In current TVs, these times t, and t2 are determined <B> to </ B> using two potentiometers mounted on the tube board. The adjustment of the image to dimensions 4/3 is therefore done manually with all the disadvantages of inaccuracy, instability and, ultimately, toil.

The present invention aims at automating the setting of 4: 3 images on a television or television monitor <B> 16/9 </ B> and, more generally, the image adjustment. smaller than the screen, by erasing strips.

<B> A </ B> This effect, the invention relates to a television monitor comprising a screen, means for receiving a video signal to send it on the screen, means for blocking the video signal means receiver and control means of the locking means, characterized in that said means for controlling the locking means comprise means for generating, from a synchronous reference signal with the signal video, a pulse signal <B> to </ B> pulse of predetermined position and width.

Thanks to <B> to </ B> the invention, one can easily and automatically predetermine the two instants, during each line, <B> where </ B> must stop the blocking of the video signal, corresponding to the trailing edge the first erasure band, and where must restart the blocking, corresponding to the front edge of the second erase band.

Preferably, the means for generating the pulse signal comprise a PWM generator and means for comparing the reference signal with a constant value signal representative of the duty cycle of the output signal of the PWM generator.

The advantage of this particular embodiment lies in the ability to adapt the duty cycle <B> to the desired time difference between the trailing and trailing edges of the two erasing sidebands, without using a converter. digital / analog to provide the constant value signal, which serves as the setpoint value.

Advantageously, the means for generating the pulse signal comprise a very high voltage transformer of the television set and, more particularly, the secondary of this transformer, supplying an electron-generating filament of the barrel of a tube and whose potential difference <B> at </ B> its terminals serves as a reference signal.

The invention will be better understood by using the following description of the preferred embodiment of the television monitor of the invention, with reference to the accompanying drawing, in which <B>: </ B> <B> - </ B> Figure <B> 1 </ B> is a block diagram of a television with the monitor of the invention, <B> - </ B> Figure 2, formed of the figures <B> 2A, </ B> 2B and <B> 2C, </ B> illustrates the temporal shape of various signals. The television shown, generally referenced <B> 1, </ B> comprises, in this example, a tube <B> 18 to </ B> cathode rays and a tuner or tuner <B> 17, </ B> <B > 27, at </ B> serial output capacitor <B> 16, </ B> to send on the tube screen <B> 18, </ B> expected for a <B> 16/9 format image , </ B> a video signal, received here by an antenna.

The reference <B> 27 </ B> denotes conventional amplifying amplifiers of antenna signals and demodulators, which depend on the signal transmission medium, wireless as here, by cable or provided by a connection socket of a VCR. The rest of the television circuits <B> 1 </ B> constitute a television monitor according to the invention. The reference <B> 17 </ B> denotes circuits for receiving demodulated video signals from the circuits <B> 27, </ B> and for formatting them, circuits <B> 17 </ B> which control a video gate electrode <B> 182 </ B> of tube <B> 18. </ B>

The TV <B> 1 </ B> is connected by a connector not shown, <B> to </ B> a controller 20 to set the factory picture of the TV <B> 1. </ B>

It will be recalled in the preamble that a cathode ray tube contains an electron gun which projects a spot beam of electrons on its screen, the intensity of which is controlled by an electron beam. gate, controlled by the video signal. The beam passes between two vertical and horizontal deflection windings respectively. The horizontal deflection winding receives a sawtooth signal to gradually deflect the beam and cause it to scan <B> at </ B> each time a <B> 1 1 </ B> screen line, the vertical deflection winding being controlled the same, but more slowly, <B> at </ B> an image frequency.

The <B> 1 </ B> television has circuitry for blocking the video signal from the receive and pattern circuits <B> 17 </ B> and has circuitry for controlling the blocking circuitry. By <B> there </ B> is meant that the blocking circuits prevent any video signal from being rendered on the screen of the tube <B> 18, </ B> whether by blocking the tube <B> 18 </ B> itself, by temporarily blocking the emission of the cathode ray beam, or by blocking, <B> to </ B> a black level, pixel signals that <B> y </ B> are applied . The blocking circuits comprise a polarization control gate electrode <B> 181 </ B>, of the tube <B> 18, </ B> which is biased to ground by a resistor 12 with a parallel <B> diode > 11 to </ B> cathode <B> to </ B> the mass. The polarization electrode <B> 181 </ B> can have, <B> to </ B> the forward diode direct voltage, a substantially zero voltage allowing the return of the video signal <B> to </ B> > the screen by video gate control <B> 182, </ B> or a negative voltage, reaching here about -200 V, blocking the tube <B> 18 </ B> and thus blocking the video signal , whose fictitious restitution then takes the form of a black part of the image, by the absence of emission of electrons by the barrel <B> to </ B> electrons of the tube <B> 18, </ B> not shown.

The control circuits of the blocking circuits comprise a comparator <B> 9 </ B> consisting of an operational amplifier with a looping resistor <B> 8 </ B> with hysteresis of its output on a non-inverting input having upstream a series resistance <B> 7. </ B> The output of comparator <B> 9 </ B> is connected <B> to </ B> the polarization grid <B> 181 through </ B> capacitor <B> 10. </ B>

Comparator <B> 9 </ B> receives <B> at </ B> through resistance <B> 7, </ B> of a control bandpass filter <B> 6 </ B> reference alternating signal, synchronous with the video line signal of the tuner <B> 17, </ B> that is to say the same line period as this one. The filter <B> 6 </ B> has a series inductor connected to a parallel output capacitor, tuned to oscillate on the line frequency of the video signal, with a period of about 64. For this, in this example, the oscillating filter <B> 6 </ B> is connected, by a capacitor <B> 26 </ B> to the input, <B> to </ B> a secondary winding <B> 23 , </ B> of a transformer, heating a <B> 183 </ B> <B> tube to </ B> electrons from the tube <B> 18. </ B>

The alternative signal of the winding <B> 23 </ B> for heating the filament <B> 183, </ B> its precise shape is unimportant, but it presents a parasitic return line pulse which is here used to excite the filter <B> 6. </ B> This pulse is due to the fact that a transistor 21 for controlling the primary 22 goes <B> to the off state, to bring back <B> to </ B> zero a sawtooth horizontal deflection current of the electron beam from the barrel of the tube <B> 18, </ B> controlling the line deflection winding. The oscillating filter <B> 6 </ B> thus provides a signal oscillating <B> at </ B> the line frequency of the video signal. The transformer considered here is a very high voltage transformer, a second coil 24 provides a high DC voltage to the tube <B> 18 to </ B> through a rectifying diode <B> 25 </ B>.

The comparator <B> 9 </ B> receives, on its inverting input, a continuous and adjustable reference voltage from an image adjustment chain of the tube <B> 18, </ B> received <B> to </ B> a 4/3 format.

The setting chain, or control blocking the restitution of pixels out of 4/3 image format, or slightly less in width to hide the vertical edges, includes a memory 2 writable from the controller 20, which is read by a microprocessor <B> 3 </ B> to supply the control DC voltage to the comparator <B> 9. </ B> This voltage allows (fig. <B> 2A) </ B> to adjust the width and the position of the useful video image 34 by adjusting the width of the black edges <B> 33, 35 </ B> which surround it. The controller 20 having entered, in memory 2, a shape factor value representing, directly or indirectly, the ratio between the width of the useful image 34 and the width of the total image with the black edges <B> 33 , 35, </ B> this value is applied to comparator <B> 9 </ B> as the reference DC voltage, or setpoint. This reference value may, if necessary, be modified by the controller 20, having then sensors for reading the screen of the tube <B> 18, </ B> or possibly after control of an operator observing the result obtained <B > to </ B> the tube screen <B> 18. </ B>

In this example, the above form factor value is converted to the reference continuous value by passing through a PWM circuit controlled by the microprocessor <B> to </ B>. > 3 </ B> to reproduce in time the form factor represented in memory 2. The pulse output of circuit 4 is applied to the comparator <B> 9 to </ B> through a low-pass filter <B> 5, at a large time constant in front of the repetition period of the pulses, thus providing the reference or reference continuous signal in the form of the average value of the signal of the PWM circuit 4, ie a constant value representing its duty cycle, and thus representing the form factor in memory 2. Thus simply transforms the form factor value, memory 2, or absolute duration of the corresponding image 34, into a DC voltage amplitude. It will be understood that, as it is a question of obtaining a desired DC voltage, from PWM pulses of fixed amplitude whose width is adjusted, the frequency of repetition of the pulses of the circuit PWM 4 is independent of that of the video signal. In other words, the PWM circuit 4 and the low-pass filter <B> 5 </ B> are the equivalent of a chopper circuit transforming a determined value in memory 2 into a proportional DC voltage <B> to < / B> this value.

Figure <B> 2A </ B> represents, as a function of time t, the amplitude of the line video signal of the shaping circuits <B> 17, </ B> Figure 2B represents the input signals of the comparator <B> 9, </ B> Figure <B> 2C </ B> represents the input signal of the oscillating filter <B> 6 </ B> that triggers the <B> 9 comparator. </ B> The modulation of the video signal is here positive type, that is to say that a zero level corresponds to black and that the positive amplitude of the video signal represents the white level. However, the invention is also applicable <B> to </ B> a <B> negative modulation monitor, for which the blocking of the video signal at the black level would consist of <B> to </ B> force it <B> at </ B> the expected maximum positive dynamic voltage.

The video signal shown comprises, in order, a negative pulse <B> 31 </ B> of line synchronization, a range <B> 32 </ B> of dead time, a first range <B> 33 </ B > black video image, a useful image area 34, the width for the 4/3 format, a second black video image range <B> 35 and a short range <B> 36 </ B> dead time for the return line of the cathode beam. It will be noted that, as mentioned above, it is possible to act directly on the polarization grid <B> 181 </ B> or on the video signal that is applied <B> to </ B> the video grid <B> 182 < / B> to produce the black ranges <B> 33, 35. </ B> The representation of the image <B> 33, </ B> 34, <B> 35 </ B> part of the video signal corresponds to the case in which we would block this signal at zero level of black. In this example, the same blocking result at the black level, or infranoir, is achieved by temporarily shutting down ("blanking") the barrel <B> to </ B> electrons during ranges <B> 33 </ B > and <B> 35. </ B> The useful range of non-zero video signal, different from black, could therefore in fact cover in whole or in part the ranges <B> 33, 35, </ B> but with a null effect since the tube <B> 18 y </ B> is then blocked. For the sake of simplicity of explanation, we drew a signal <B> 33, </ B> 34, <B> 35 to </ B> two black ranges, equivalent to a wider video signal 34 and framed by ranges <B> 33, 35 </ B> corresponding in reality to the blocking of the barrel <B> to </ B> electrons. It is also possible to limit the line scan <B> to </ B> the useful area (34) by limiting the dynamics of the line scan sawtooth signals.

References 41 in Figure <B> 2C </ B> represent the line return overvoltage pulses <B> 23 </ B> which are used here to synchronize, on the line video signal, the action of the comparator blocking <B> 9 </ B> producing negative gate blocking pulses <B> 181 </ B> to produce black ranges <B> 33 </ B> and <B> 35. </ B > The secondary <B> 23 </ B> of the transformer, supplying the <B> 183 </ B> of the <B> electron tube <B> 18 </ B> to the electrons thus provides, by the difference of the potential <B> at </ B> its terminals, the reference signal, synchronous with the video signal.

The alternating signal 42 represents the line return signal 41 after filtering in the oscillating filter 6, a phase rotation of 180 degrees has been produced by crossing a non-amplifying amplifier. represent. Reference 43 indicates the continuous reference signal derived from the low-pass filter <B> 5. </ B> As shown in FIG. 2B, the alternating signal 42, <B> at </ B> line frequency, has an extremum , here high, in medium (34) of video line and an opposite extremum in the period of beginning and end of image, <B> where </ B> are the pulses 41 which engender it. The line synchronization pulses <B> 31 </ B> could have been used, <B> to </ B> instead of the line return pulses 41, to provide the AC signal 42. An adjustable phase-shifter can be provided as input or output filter <B> 6 </ B> to center the image 34. This is for example a line <B> to </ B> delay, <B> to </ B> to inductance series and capacitor parallel to output, or a low-pass filter which eliminates more or less harmonics and thus allows to deform the signal of the oscillating filter <B> 6 </ B> to change differently the times of tripping and stopping of the comparator <B> 3. </ B> The continuous reference signal 43 is located between the two extremes above, so that the comparator <B> 9 </ B> has a low output of -200 V in a period of time substantially centered on the pulse 41 (and <B> 3 1), </ B> corresponding to the blocking of the rendering of the video signal of the tuner <B> 17, </ B> which produces the ranges <B> 33 </ B > and <B> 35 </ B> black. The intersection point 46 of the signals 42 (upstream) and 43 has a delay t1, the end of the black range <B> 33, </ B> on the line synchronization pulse <B> 31 </ B> and the homologous point of intersection 47 <B> at </ B> the descent of the signal 43 has a homologous delay t2, the beginning of the range of black <B> 35. </ B> A modification of the value of the signal Continuous reference 43 makes it possible to modify, in opposite directions, the values t1 and t2 determining the width of the black ranges <B> 33 </ B> and <B> 35, </ B> and thus to adjust the image width useful 34.

In the case of a blocking action at the video signal, so by a control of the video grid <B> 182 to </ B> through the shaping circuits <B> 17, </ B> the output the <B> 9 </ B> pulse signal would control an inhibition input <B> 171 </ B> at a video gate of the <B> 17 </ B> shaping circuits video signal the tube <B> 18, </ B> to block it at the black, zero voltage in this example. This command, of inhibition or not of the video signal, then consists of a logic signal of limited dynamic <B> to </ B> a few volts.

It is conceivable that the invention also applies to non-tube television monitors, for example so-called flat screen monitors, in which the screen is consisting of a matrix of punctual elements, stimulating light emitters and individually excited by addressing them in the matrix.

Claims (1)

CLAIMS <B> 1 .- </ B> A television monitor comprising a screen <B> (18), <B> means (17) </ B> for receiving a video signal for the send on the screen <B> (18), <B> means (171, 181, 182) </ B> to block the video signal of the receiving means <B> (17) </ B and means <B> (2-6, 9, 21-26) </ B> for controlling the blocking means, characterized in that said means <B> (2-6, 9, 21-26) </ B> of the blocking means <B> (171, 181, 182) </ B> comprise means <B> (3-6, 9, </ B> <B> 21-26) </ B> to generate, from a reference signal synchronous with the video signal, a pulse signal <B> at </ B> pulse of predetermined position and width. 2. A monitor according to claim 1 wherein the means for generating the pulse signal comprise a PWM generator (4) and means for comparing the signal of the signal (FIG. reference with a constant value signal representative of the duty cycle of the output signal of the PWM generator. <B> 3 .- </ B> Monitor according to one of claims <B> 1 </ B> and 2, wherein the means for generating the pulse signal comprise a transformer (22 24) very high voltage supply a tube <B> (18) </ B> from the TV. 4. A monitor according to claim 3, wherein the transformer secondary (23) of the transformer supplies a gun <B> (183) </ B> heating wire < B> to </ B> electrons of the tube <B> (18), </ B> whose potential difference <B> to </ B> its terminals serves as a reference signal. <B> 5 .- </ B> Monitor according to one of claims <B> 1 to </ B> 4, wherein the pulse signal controls an inhibition input of the receiving means <B> (17). </ B>