DE2627338B2 - Television receiver with a circuit arrangement for the simultaneous playback of several programs - Google Patents

Description

runs slowly through, whereby due to the ongoing mutual phase shift of the synchronization pulses the blanking gaps appear as black bars in the image section at certain times. In the known arrangement must therefore be adjusted by hand actuators so that the image section is faded in at another point of the main image, so again one To get a "bar-free" cutout. Compared to this known prior art sol! in the Invention, the fade-in take place in such a way that the faded-in section is automatically dependent on the position of the sync pulses of the additional transmission signal on a sector free of blanking gaps of the screen is displayed.

The main application P26 14 199.1-31 preceding this invention was therefore based on the object to find a circuit arrangement which manages without such a memory arrangement. The invention is based on the knowledge that it is often sufficient to only add part of the further program to the main program to be displayed, since the viewer only wants to be informed whether a the program of interest has already started. This can be done through a section of the image to be monitored Program can be easily identified. Here, the faded-in image section is displayed in a ratio of 1: 1, i.e. H. with same resolution as the main picture.

In the main application it was therefore proposed that for each program one tuner, one each Intermediate frequency amplifier and a pulse separator are provided, each of which has horizontal frequencies and vertical-frequency output pulses are taken, which in their phase position in a Comparison circuit are compared, the comparison circuit both depending on the Phase position of the horizontal and vertical sync pulses actuates an electronic switch, the one selected by the comparison circuit, free of blanking impulses image section of the second Program as a rectangle fades in such a way that any corner point with a corner of the screen matches. In the solution disclosed in the main application, the comparison circuit has two bistable multivibrators, at whose first inputs the horizontal-frequency and vertical-frequency respectively Synchronization pulses of the television signal with the first programs, and at their second inputs the over monostable multivibrators delayed sync pulses are switched. The outputs of the two bistable Flip-flops are used to determine the mutual phase position of the sync pulses together with the horizontalfrequenten or verticalfrequente.n synchronizing pulses of the television signal with the second Program connected via a logic link, with the outputs of the logic circuits on one input of two further bistable flip-flops are connected, their outputs together are linked to the outputs of the first-mentioned bistable multivibrator in such a way that only during of the time segments of the line and image trailing of the electron beam which are free of blanking pulses Switchover to playback of the second program signal takes place.

The present invention is based on the object of simplifying the structure of the comparison circuit. This object is achieved by the measures disclosed in the characterizing part of claim 1.

The invention will be described in more detail below using an exemplary embodiment with the aid of the drawing. It shows
F i g. 1 shows a block diagram of the circuit arrangement, FIG. 2 shows a detailed block diagram of the comparison circuit used in the circuit according to the invention,

F i g. 3 a timing diagram,
F i g. 4 one divided into sectors for insertion

ίο image grid.

The invention assumes that the transmitter that use the PAL color television standard, emit a signal which has a fixed coupling between the row, screen and color subcarrier frequency, since the color subcarrier is required to have an accuracy of 10 ~ ^6, is a very exact match the line and grid frequency guaranteed from transmitter to transmitter. It is possible to mix the video information of a transmitter A with that of a transmitter B , or to blend the information of transmitter B into the information of transmitter A. Due to the small frequency differences, however, the synchronizing pulses from transmitter B will generally be phase-shifted with respect to the synchronizing pulses from transmitter A , and this phase shift will be noticeable as a very slowly scrolling image. The phase shift between the sync pulses from two transmitters can also be caused by the geographical location between them. The synchronous and blanking pulses contained in the video information from transmitter B thus reach the visible area of the image section, which is represented as horizontal and vertical black bars. If you divide the screen into 4 sectors, I, II, III and IV, you will find that one sector is definitely free from these annoying bars. The circuit arrangement according to the invention now automatically selects this bar-free sector and reproduces the video information from the transmitter that is currently present in this sector.

In the following, a circuit design will be described using an exemplary embodiment which brings about this automatic sector switching
In Fig. 1, the television signals from two transmitters reach the antenna 1 via an antenna splitter 2 in two tuners 3 and 5 that are matched to the transmitters. B. the selected by the tuner 3 signal come from the transmitter A , which are shown on the screen as the first or main program

so should. The signal arrives in the usual way at an IF amplifier 4, from where it arrives via a sound stage 12 to the brightness amplifier stage 6, which is connected to the picture tube 8. At the same time, the synchronizing pulses are processed in the pulse separation stage and deflection output stage 7, from which the deflection currents for the deflection unit 10 are obtained. In the case of a color television receiver, the color signals reach the color amplifier stage 11. The additional program of transmitter B received by the tuner 5 arrives at the IF amplifier stage 9 and from there also into the brightness signal amplifier 6 via the switching stage 12, to which the other program is also connected In addition, the signal from the IF amplifier 9 is applied to an amplitude filter 13, which supplies the horizontal-frequency and vertical-frequency synchronizing pulses to a phase comparison stage 14 which, with the vertical-frequency and horizontal-frequency synchronizing pulses from the amplitude filter and deflection stage 7

of the other signal can be compared. The phase comparison stage 14 now switches the switching stage 12 as a function of the phase position of the synchronizing pulses in such a way that the additional program of the transmitter B appears on the screen of the picture tube 8 at the right moment. The video signal of the second program is therefore constantly on hold at switch 12 until it is called up and switched on to brightness amplifier stage 6. At the same time, the color amplifier stage 11 is blocked by a blocking pulse, if it is a color television. The circuit arrangement is also applicable to a black and white television receiver.

In the following, with the aid of FIG. 2 the process of phase comparison and the generation of the for the switching stage 12 required switching signal described.

First of all, it should be explained how the comparison circuit 14 determines the part of the screen grid that is free of horizontal-frequency synchronizing pulses of the program signal to be faded in, in order accordingly to put the switching stage 12 into the correct switching phase. For this purpose it should be assumed that the image grid is divided into four quadrants I to IV, as shown in FIG. 4 is shown. Quadrants I to IV are separated from one another by the horizontal X axis and the vertical Y axis. When comparing the horizontal sync pulses HX and H 2 of the two program signals, it is important to determine whether the sync pulse H 2 is in the left or right part of the image grid divided by the line Y. For this purpose, a pulse series with double frequency is first produced from the sync pulses Wl of the first program signal, in that these sync pulses are delayed via monostable flip-flops 15, 16 switched to another monostable flip-flop 17, the latter having two inputs, the flip-flop 17 via one input is triggered with the positive edge of the pulse HX and via the second input with the negative edge of the pulse taken from the flip-flop 16. This creates the desired pulse sequence as shown in FIG. 3 from the pulse series a, b, cent stood at (/ is shown. The pulse sequence according to FIG. 3d is given firstly to a NOR gate 18 and secondly to the clock input of an edge-controlled flip-flop 19, which is thus used as a frequency divider 2: 1. The sync pulse sequence H2 of the second program signal is applied to a second input of the NOR gate 18, however, inversely to the pulses HX (FIG. 3f, g, h). Depending on the phase position of the pulse series (FIG. 3d, f; d, g, respectively d, h) are formed pulses after Fig.3i or k entering the direct reset input / of flip-flop 19 are created as a result, at the output Q of flip-flop 19 circuit voltages with the 180 °?. phase shifted phase positions according to Fig. 31 or m - depending on the times at which the pulses according to Fig. 3i or k arrive at the reset input.

It is now assumed that the phase difference between the two sync pulse trains HX, H2, which had just agreed in their phase position (Fig. 3a, f), has increased slowly due to the small frequency difference, so that the sync pulse H 2 of the program signal to be inserted into the visible part of the left half of the picture (Fig. 4 Quadrant I, III).

ίο At this moment, the NOR gate 18 gives a pulse to F i g. 3i) to the direct reset input R of the flip-flop 19, so that it is immediately switched to a defined phase position (Fig. 31), which is retained until the sync pulse H2 falls into the right half of the screen (Fig. 31). 4 Quadrant II, IV). Then namely during this time the pulse reaches Fig. 3k to the reset input R of the flip-flop 19, so that it is forced into the opposite switching phase (FIG. 3m).

The comparison circuit operates in the same way with respect to the vertical frequency sync pulses (Vi, V2). A decision is made here as to whether the synchronizing pulse V2 of the program signal to be faded in is in the upper or lower half of the screen. The quadrants I -II -III-IV formed by the dividing lines XY are scanned in the horizontal direction Λ and vertical direction ν. In the illustration according to FIG shows the current program part of the first program for the duration of the second line and the upper half of the screen. Because of the equivalent mode of operation with reference to the comparison process of the horizontal sync pulses just described, the description relating to the comparison of the vertical sync pulses is dispensed with. The reference symbols in FIG. 2 are accordingly provided with an index.

In order to hide the porch of the second program signal when switching to the other quadrant in the temporal position around the dividing lines XY of quadrants I-IV (Fig. 4), the switching stage 12 is not activated during the times indicated by the hatching, which is achieved by an additional monostable multivibrator 21 connected to the monostable multivibrator IS is achieved, the output pulses of which according to FIG. 3e are placed on the NOR gate 20.

At additional inputs of the NOR gate 20, further pulses can be applied to the second Hide program signal at defined times, e.g. B. to the image blanking pulses at the top and bottom Make the edge of the second program signal invisible.

For this purpose 4 sheets of drawings

Claims (2)

Patent claims: 1. Television receiver for receiving various television broadcasts with a circuit arrangement with which video signals of a first and a second program signal can be switched via an electronic switching stage so that an image section of the second program signal appears on the television screen in an image section of the reproduced first program signal is made visible, whereby a tuner, an intermediate frequency amplifier and a pulse separation stage are provided for the reception of two different programs, from which horizontal-frequency and vertical-frequency synchronizing pulses are taken, which are compared in their phase position in a comparison circuit, the comparison circuit being dependent on the position of the horizontal sync pulses and the vertical sync pulses of the second program signal in relation to the horizontal sync pulses and vertical sync pulses of the first program signal the ele Ctronic switching stage operated in such a way that the video signal of the second program signal is faded in in a picture section of the video signal of the first program signal, which is free of blanking pulses of the second program signal, in such a way that any corner point coincides with a corner of the screen according to patent application P 26 14 199.1, characterized in that the comparison circuit (14) has a bistable multivibrator (19, 19 ') connected as a frequency divider with static reset inputs (R, R') and a clock input (T , T) and that an output of a NOR gate (18 or 18 ') is connected to the reset inputs (R, R') , and the synchronizing pulses to be compared (HX, H 2; VX, V 2) are placed in mutually opposite polarity, and that via monostable multivibrators (15, 16, 17 or 15 ', 16', 17 ') the at the input of the NOR gate (18 or 18') and Synchronous pulses (HI, VX) of the first program signal applied to the clock input (T or T) of the bistable multivibrator (19 or 19 ') are doubled in frequency, and that the outputs (Q, Q') of the bistable multivibrator (19, 19 ') are linked to one another via a NOR gate (20), the output of which actuates the switching stage (12) to fade in the second program signal. 2. Television receiver according to claim 1, characterized in that the NOR gate (20) via monostable multivibrators (21, 21 ') additionally delayed sync pulses (HX, VX) of the first program signal are connected. 60 The invention relates to a circuit arrangement for a television receiver with a screen, on which a first program is played, as well as with a bucket device in the television receiver, by means of the at the same time in an image section of the reproduced first program at least one Image section of another program is made visible. There are already television receivers known in where several programs can be viewed at the same time by adding at least one additional smaller TV screen is attached next to the main screen. However, this arrangement is very expensive, since several complete receiving parts are also required. In order to save the additional screen, it was therefore proposed to display at least part of an additional program in a section of the main picture. So is z. B. a method for combining several television images recorded by different image recording cameras and reproduced together on the same receiving screen, known (DBP 10 09 228). This method is characterized with its main feature in that the deflectors are traversed across the image pick-up tubes of the same deflection. As a result, this method is limited to television systems that work in so-called short-circuit mode. The same applies to the method according to DAS 10 49 907, in which for the simultaneous visualization of several video signals originating from different television scanners on the same receiver screen, in addition to the horizontal and vertical frequency sawtooth pulses for the deflection systems of the television scanners, additional sawtooth pulses are generated and the deflection systems of the television receiver are supplied whose pulse repetition frequency is an integer fraction of the horizontal and / or vertical sawtooth pulses. To view the television signals broadcast by different television channels simultaneously on one screen To reproduce, it has been proposed to insert a reduced size in the reproduced picture of the main program The image of the additional program is to be displayed (DT-OS 24 13 839). A memory is used here, which is described in detail in DT-OS 24 04 237. The memory has the task of the image further Program and the time difference between switching to the channel further Program and the playback of this information. The reduction of the image further Program is achieved in that the output speed for the memory is greater than the input speed is. In this case, however, the image reproduced in a reduced size has a lower resolution in the vertical direction, since only about every 14th line of the displayed program is saved and played back will. It is also known, for example (DE-OS 23 14 289), a television receiver with means for monitoring of a room by a television camera or a second broadcast. With this plant also via a single screen and with the help of an electronic switching device to predeterminable Make a second image visible on the screen. For this purpose, actuators are provided, with which the size and / or the position of the superimposed image or part of the to be monitored Image is adjustable. When playing two different programs at the same time With two different transmitters, the difficulty arises that due to the small frequency differences the synchronization pulses of the transmitter the second superimposed picture in relation to the main picture