DE686597C - Television reception method for transmission systems with intensity control - Google Patents

Description

Television reception method for transmission systems with intensity control In all television transmission methods that use a constant scanning speed work, the disadvantage arises that sharp contours, i. H. sharp light-dark transitions, are displayed blurred due to the finite size of the scanning openings, if it is a perforated disk scanning or. as a result of the finite Size of the scanning cathode ray spot, provided the image decomposition by means of a agitated Katho, the beam is made.

The sharpness of the contours of the received image is, among other things. on the size and The shape of the scanning spot used on the transmitter side depends. Even when in use of a rectangular scan patch of the smallest possible dimensions is that The sharpness of the contours reproduced in the received image is blurred due to the finite bandwidth of the transmission channel.

On the basis of FIGS. I and 2 should first be shown how a certain dark-light transition in a television picture changed by scanning will. If the dark-light transition is assumed to be discontinuous, i. H. such as it is drawn in Fig. i, then when scanning with an approximately round perforated disc opening or a cathode ray with a round cross-section generates a transmission current, as illustrated in Fig.2. Assuming a light or cathode ray bundle with a negligible cross-section in the television receiver, the discontinuous one would then be Dark-light transition of Fig. I of the original image on the receiving side so reproduced as Fig.2 shows. So there would be smooth contours, and the reception image would therefore appear out of focus.

According to the invention it is now proposed on the receiving side derive an additional line control from the transmission current. So it should in the case of the television receiver, in addition to the intensity control according to FIG a modulation of the writing speed takes place and this additional control, which is derived from the image currents tüid is dependent on the changes in intensity the same, causes a greater sharpness of the image, without any noticeable Distortion of the image occurs. One of the possible embodiments is closer explained.

By known means, a voltage is generated in the receptions-h, the circuit of the first waste. of the transmission current is proportional to the time. This derived Spärinung thus runs as shown in FIG. 3. The voltage now causes an additional deflection of the beam forming the image, which is, of course, deflected at a constant speed. This can e.g. B. happen in receivers with cathode ray tubes that the additional voltage is fed to the line deflection plates. This principle can also be used for the magnetic deflection of the cathode ray. It is then only necessary to derive current from the transmission current min, which corresponds to its first derivation with respect to time, and this derived current is to be fed to the line deflection coils in which the linearly increasing line deflection current also flows (so-called line sawtooth).

FIG. ¢ shows the path-time diagram of the beam without additional deflection (Straight line x,) and with additional deflection (curve x2). X means the coordinate the line direction and t as well as in Fig. i to 3 the time.

5 shows the intensity profile over the line. The curve J, corresponds to the straight line x1 in FIG. H. one only with constant Speed going distraction. The curve J2 shows the intensity profile, as he did taking into account the curve x2 in Fig. q. comes about. Already this one both curves. show the increase in contour sharpness achieved by the additional deflection. Now it should be noted that the brightness H effective for the eye is proportional the intensity J, but inversely proportional to the writing speed v. Due to the additional distraction, however, the writing speed is now also corresponding the differential quotient of the intensity changed over time. This differential quotient is for the straight line x, in Fig. q. by the straight line v, drawn in and for the curve x2 through the curve v2.

The course of the brightness H effective for the eye over the line coordinate x is shown in FIG. In this the brightness curve is H1 for the case that it is only worked with a constant deflection speed, so for the Case of the curve xi in Fig. Q. the same as given by curve J1. For the mode of operation with an additional deflection according to the differential quotient of the transmission current, however, is the brightness distribution that is effective for the eye even steeper than curve J2 shows, namely roughly as shown by curve H2 is specified. The comparison of the curves HI and H2 shows to what extent a Sharpening of the dark-light transitions can be achieved by the invention.

In the above explanations with regard to FIG. 3, simplicity tacitly provided that the cross-section of the receiving end Light or Cathode ray tufts should be negligibly small. If you have this If you want to drop requirements, a certain amount also occurs on the receiving side Flattening of the transition in brightness. However, that is what the invention is aimed at Purpose, the brightness transition by means of an additional modulation of the scanning speed to improve the reception image, nevertheless achieved.

The explanations given above for the improvement of the dark-light transitions apply mutatis mutandis to the improvement of light-dark transitions.

The added distraction of a dem corresponding voltage is only one embodiment of the inventive idea. It can be carried out by means of all devices known for line control, including in cathode ray receivers by influencing the resistance of the charging tube for the line deflection by a variable derived from the intensity curve.

The output signal of the photo element used on the transmitter can reproduce better contour sharpness when using a rectangular scanning spot, than is possible when using a round scanning spot. The transfer such an output signal to the receiver is successful because of the finite Bandwidth of all transmission channels is not perfect, so that at the receiver again blurred contours of the same type as shown in FIG are. The invention is therefore also applicable to the use of rectangular scanning spots on the transmitter applicable with success.

Claims (1)

PATENT CLAIM: Television reception method for transmission systems with constant scanning speed at the transmitter and intensity control of the image building Light spot on the receiver, characterized in that in addition to this intensity control on the receiving side continuously the image build-up speed is controlled with the help of an additional, acting on the deflection organs, respectively on the temporal course (steepness) of the intensity changes dependent signal. which acts on the diverting organs in such a way that the impression of a larger Image sharpness arises than when the intensity control is used exclusively.