DE2137613C - - Google Patents

Description

punching of the bandfil control of the receiver, which is matched to the interference frequency.

no high demands have to be made,

sen. In FIG. 2, the same functional elements are seen before further advantages are seen from the description of FIG. Not 5 image signal at the input, "declined, but FIG. 1 shows the IMPROVE" clothes the earlier pre- behind the limiter ti z at the output. This signal from the circuit arrangement, FIG. 2, is again fed via a Logarilhmicrer L, an application of the interference frequency taken from the output of the circuit arrangement BP and possibly a limiter BO de ™ to control the interference frequency taken from the second input of the divider. This pure interference frequency to be fed in, FIG. 3 io parallel path, is designed here as a control loop, the supply of the directly derived from the light stimulus, ie that any interference still present at the output ζ is a pure interference frequency, FIG The amplitude of the interference frequency obtained over the second pure interference frequency from the interference frequency of the circuit arrangement still present at the output output of the divider is correspondingly reduced or increased until the sequence, FIG. 5, the optical extraction of the interference output signal is interference-free.

Image signal from the beam path of the recording The circuit arrangement according to FIG. 3 is similar and the addition of the pure interference frequency to the borrowed according to FIG. 1 built. Via the logarithmic, disturbed image signal with an electro-optical modulator L, the bandpass filter BP, a possibly predulator and F i g. 6 the same optical extraction manual limiter BG and a rectifier study of the disturbed image signal, but the addition of the 20 FeG, which brings the interference frequency obtained up to now to its interference frequency via a grid of the recorders peak G the mean value, a control tube, voltage is obtained, which is the gain factor

According to FIG. I the jammed, disturbed image of a control amplifier RV is controlled,

signal via the input "of the circuit arrangement via the input" but at the same time the

fed. This signal has the form, for example, 25 mains frequency 50 Hz to a frequency doubler F,

as in the one drawn above the input line, at its output the pure interference frequency for a

Diagram can be seen. The curve is made up of further processing that is available. This fr

several sequences recorded by the same line cannot be transmitted to the divider D

Image signals together, in which, however, the image is added because the luminous flux is a

The subject of a fluorescent lamp caused by the mains frequency generally has a phase difference

is exposed to fluctuations in lighting. During the shift of about 60 compared to the grid phase

Has black level recorded as a sharp line. This is why it is a phase shifter

j, the gray values and the white value consist of Pk , the phase of which is the interference frequency

ρ ■ several superimposed lines. rotates far so that it

/ I This image signal is applied directly to the control amplifier ₃₅ strengthening RV the second input

} one of the two inputs of the divider D. gang of the divider Z) can be fed.

At the same time, however, it also achieves an interference frequency in the parallel path, which is implemented in the image signal ■ logarithmic element L, which is preferably added as a logarithm, the parallel path with the amplifier acting in it. In this held switching elements does not go through, it can logarithmize, the image signal is proportionally 40 also through the bandpass filter and the other elements of the relative light fluctuation and regardless of not be distorted. The respective image amplitude must be constant at these links. consequently no high phase constancy

From the logging element L comes the signal requests to be made,
on a bandpass filter BP. Assuming that In F \ g. 4 if the switching network frequency is 50 Hz in a modified form, a lighting arrangement according to FIG. 4 arises. 3 shown. Here there is a keitsschwankung of 100 Hz (interference frequency), to which, however, again, as described with reference to FIG. 2, the bandpass filter BP is matched. The 100 Hz oscillation, which has been filtered out by the bandpass filter, is used to control the control amplifier of the interference frequency component of the disturbed picture RV . In this way, the amplitude corresponding to the signal is also fed to the second input 50 amplitude of the pure interference frequency in the control gain of the divider D. ker RV automatically on one to compensate for the

In an extended circuit arrangement, interference frequency can be brought to the necessary size,

after the band filter BF there is also a limiter BG in FIGS. 1 to 4 described so far

be joined, which shows an overcompensation in the event that the disturbed image signal! for the parallel

The absence of real 100 Hz vibrations is prevented, 55 is tapped off electrically. It is

that result from movement processes in the picture. but also possible to use this signal optically

In the divider D one can see by dividing the two, as in FIG. 5 and 6 is shown.

Signals the disturbed image signal is transformed as in FIG. 5, the modulated signal falls from the left

the curve above the divider D shown. Light via an optical system OS onto the recording

As can be seen therefrom, the swan tubes R appear between the optical system OS and

only in the line blanking interval. the tube / Ϊ there is a slanted, partially

The divider is followed by a limiter B transparent mirror, which modulates part of the sound

that cuts away the line blanking gap, as in light - possibly via another optical one

the curve drawn above the limiter B - system - diverts to a photocell FZ . This fo-

is posed. 65 tozelle transforms the light fluctuations into electrical

The cleaned signal is then available at the output ζ see fluctuations which, as already described,

for impulse admixture available. There are a logarithmizer L, a bandpass filter and BP

now again the line blanking interval as well as the possibly further functional elements of an electro-opti-

see modulator mod are fed. This modulator is inserted between the mirror Sp and the tube R in the beam path and takes on the function of the divider there. Its light transmission is controlled electrically so that the fluctuations in brightness are compensated and an interference-free optical signal reaches the pick-up tube R.

If the position of the partially transparent mirror Sp is exchanged with the modulator Mod , a control loop is created, as described with reference to FIGS.

Instead of the relatively expensive electro-optical modulator Mod , a control grid of the tube Λ according to FIG. 6 can be used. The pure interference frequency present at the output of the bandpass filter BP is fed as a grid voltage Ug to this control grid of the tube R, which may be additionally provided.

The F i g. 1 and 3 can also be modified so that the disturbed image signal, as described, optically enters the parallel path, but then the pure interference frequency to the second input of the Dividicrcrs is supplied electrically, Such a circuit arrangement is therefore particularly advantageous, because the optical signal does not yet contain any sampling frequencies and consequently does not take them into account need to become.

The invention is so far for an application at Video telephones described. But she is also with Can be used with the same success in commercial television if a recording camera is used to record the image with a short storage time, for example a plumbicon or a Si diode vidicon, used and the lighting with luminaries with a large modulation depth, for example with fluorescent lamps, he follows.

1 sheet of drawings

Claims (1)

"f (100 Hz) of the ParaHehveges (ρ) a control grid Claims: (Un ) is fed to the receiving tube (R) (Fig. 6). 1. Circuit arrangement for television display to eliminate malfunctions on the picture 5
The invention relates to a circuit arrangement for the image change frequency and the light frequency present in the recording for video telephones to eliminate interference the transmission side jpdes Bjldfernsprechers the xo in no integer ratio to each other The transmission side of each video telephone is clamped, and the image signal that has been so disturbed to the disturbed image signal is routed over a parallel path, so that the disturbances only occur in FIG. 15 by means of a band filter _. Line blanking intervals appear where they are obtained by means of interference frequency, and which are suppressed to the disturbed h "of a limiter, because the image signal is added in such a way that the disturbances γ. \ zen of the pure blanking gaps obtained in the parallel path (p) appear, where they are suppressed by means of a limiting interference frequency (100 Hz) for the disturbed image. \ signal of the direct path (d) in a divider I (D) takes place. hit, the jammed, disturbed image signal Γ 2. Circuit arrangement according to claim 1, there- first to be fed to a logarithmizer and then 1 dutch that in the parallel path (p) before ßend on the one hand a summing element directly and on the other I the band filter (bandpass filter BP) a logarithmic 35 on the other hand to obtain the pure interference frequency || member (L) is arranged. via a parallel path to the same summing element fi 3. Circuit arrangement according to claim 1, to be added, in which a subtraction of the two signals ψ. marked by the fact that the disturbed image occurs. Then a potentiating element is provided. y signal for obtaining the range of interference frequency in which the previously logarithmized image signal ( (100 H / l at the output (z) of the divider (D) _3o which by delogarithmizing into the correct ratio i% downstream limiter (B) is taken until the gray values are brought together. }: (Figs. 2 and 4). The object of the invention is now the known I · 4. Circuit arrangement according to claim 1, to simplify the circuit arrangement, in particular I characterized in that the parallel path (p) reduce the number of switching elements by the The pure «interference frequency (100 Hz) obtained through which the image signal passes. I control amplifier (RV) is fed, where it is achieved according to the invention by; Controlling the size (amplitude) of the that the clogging of the \ light network (50 Hz) obtained in the parallel path is directly derived, in dividing pure interference frequency to the disturbed image signal of the: rer (D) the image signal (d) to the disturbance sub-direct path in a divider takes place.
_t pressure to be mixed interference frequency (100 Hz) 40 The circuit arrangement according to the invention γ is used (Fig.3und4). has the advantage that three functional elements, namely I 5. Circuit arrangement according to claim 4, that the logarithmic element, the summing element and the 1 are characterized in that the pure interference frequency obtained from the lighting network by a single element, namely '(50HzJ 100 Hz) are replaced by a divider. As a result, with the help of a phase shifter (Ph), in addition to a simplification of the overall phase position with regard to the disturbed image, there is also the advantage that the interfering signal (d) contained in the interfering signal (d) - .enz brought the following logarithmization and delogarithmization is possible, falsifications of the image signal are avoided. Beam path of the recording camera (R) which is according to one embodiment of the invention the interference frequency (! 0PHz) brightness modulated the disturbed image signal to obtain the pure signal of the image for the parallel path (p) taken from the interference frequency at the output of the (Fig. 5 and 6). ordered 3limiter taken and depending on the 7. Circuit arrangement according to claim 6, there- ₅₅ size of the disturbance to regulate the size (amplitude characterized in that part of the modulating mde) of the pure interference frequency to be mixed in ί th light is used with the help of one of the pickup tube dividers. This has the advantage that with (R) upstream partially transparent mirror (Sp) of this arrangement does not have any amplitudes equal to the taken and is required via a photocell (F) to the pure interference frequency to be added, Parallel path (p) is fed. 6 ₀ because this amplitude changes automatically due to the 8. Circuit arrangement according to claim 7, there being the image signal at the output of the circuit arrangement characterized in that the pure interference frequency adjusts to the interference frequency that is present. (100 Hz) of the parallel path (p) one in the According to another embodiment of the invention The electro-optical mode inserted into the beam path controls the pure interference frequency from the light network dülatcr (Mod) , which as a divider (D) 65 directly derives the interference factor obtained in the parallel path (FIG. 5). frequency is only used to control the size (Amp! i- 9. Circuit arrangement according to claim 7, da- tude) the pure interference frequency to be mixed in. the characterized in that the pure interference frequency is advantageous in that the phase con-