DE4301258C1 - Video signal processing circuit for TV receiver or video recorder - uses line synchronisation component and image synchronised vertical pulses to identify video signal source - Google Patents

Abstract

The circuit has a synchronisation separation stage for extracting a line synchronisation component from the video signal and a vertical separation stage for supplying image synchronised vertical pulses, with a synchronisation device providing a line synchronised clock signal, the video signal processing controlled in dependence on the video signal source identified via the latter clock signal and the vertical pulses. A counter and memory stage (30) provides a signal identifying the time duration for which the video signal line synchronisation component and the vertical pulses are not synchronised, fed to a further stage (31) providing a signal with two different values dependant on whether the received signal is within, or outside, a defined range. This signal is fed through a low-pass filter to provide the control signal for the video signal processing. ADVANTAGE - Uses video signal itself to identify video signal source.

Description

The invention relates to a device for processing in Lines of split video signals with a synchronous separation stage through which from the video signal a line synchronous Signal portion is separated, with a vertical separation stage, through which an image-synchronous vertical im pulse is separated with a synchronization device, by the from the line-synchronous signal portion of the Videosi gnals a line-synchronized clock signal is generated, and with a first device through which a first signal for Control of signal processing is generated in the device that different signal values depending on the type of Video signal source.

Such a device, for example a television or VCR, the video signals can come from different Video signal sources, such as an antenna or one VCRs are fed. The video signals point each have properties specific to the signal source. At already known devices are provided with which it is decided which video signal source with the device is connected, so that thereby the video signal processing in Device to the usual source-specific properties of the Video signal can be adjusted.

These funds consist, for example, in the fact that An end socket of the device a mechanical switching device is provided with which a switching signal for the signal ver working units is generated in the device.  

Means are known from US Pat. No. 4,536,794 which when setting a specific reception channel Signal processing in the device to receive video recorder the signals is changed.

The problem with these known devices is that if a video signal source is not connected to the intended one Video signal input of the device is connected or the Carrier frequency of the video signal in a not for their kind provided channel is, the signal processing especially is sensitive to interference with the video signal. If the Signal processing in the device on a from a video recorder supplied video signal is set, but an Antennensi signal is fed in, the signal processing is sensitive against noise. In the opposite case, the signal is processed processing sensitive to fluctuations in belt speed the VCR.

In one shown in German Patent 28 54 828 Arrangement for the deflection control of a television set Phase jumps of the horizontal pulses of the fed-in video signals evaluated. For this, the charge status of a Kon changed by analog signal control.

The invention has for its object a device for Processing of video signals divided into lines with a digital device to identify the type of video to indicate the signal source at which the establishment by signal parts of the video signal itself is controlled.

This object is achieved in that the first device has a second device with which a second signal is generated by specifying the time period during which is the line-synchronous clock signal and the line-synchronous Signal component of the video signal at the time of the vertical im pulses are out of sync that the first device is a has third device, which is supplied with the second signal  and which generates a third signal, the one takes first signal value when the second signal in a specified range, and that a second signal value assumes when the second signal is outside the specified Range, and that  the first facility with a fourth facility Has low-pass character, the third signal supplied and the output signal is the first signal.

The invention is described below with reference to the figures illustrated embodiment explained in more detail. It demonstrate

Fig. 1 shows the principle circuit diagram of a device according to the invention,

Fig. 2 shows the basic circuit diagram of a device according to the invention and

Fig. 3 signal diagrams of signals occurring in the device.

The device shown in FIG. 1 is supplied with a carrier-frequency input signal via an antenna 1 , which input signal is selected in a tuner 2 . In a subsequent stage 3 , a signal lying at an intermediate carrier frequency is generated and then demodulated. At the output 16 of stage 3 there is an analog video signal in the baseband (CVBS signal). As an alternative to the antenna input 1 , a video signal can be fed in in the baseband via a connection 15 . For this purpose, input 15 is connected, for example, to the output of a tape recorder (video recorder). A switching device 14 is used to select one of the CVBS signals present at the connections 15 , 16 and to supply it to an image signal processing stage 4 . There the image signals are processed and, in the case of a color television, color-coded. Stage 4 is followed by a video output stage 5 , with which a picture tube 6 is driven.

The CVBS signal selected by the switching device 14 is further fed to a synchronous separation stage 7 , through which the line-synchronous synchronous signal component of the video signal is separated. The sync signal portion is fed to both a vertical separation stage 8 and a horizontal synchronization device 9 . Through the vertical separation stage 8 , a vertical pulse applied to its output 20 is obtained, which serves as a start pulse for the image change. The Horizontalsynchronisationsein device 9 has an output terminal 18 at which a line clock coupled to the synchronizing signal portion of the video signal is present. The vertical pulses and the line clock are supplied to a horizontal and vertical deflection device 10 , by means of the output signal of which the deflection device of the picture tube 6 is controlled.

The horizontal synchronization device 9 essentially contains a horizontal phase locked loop 13 , which generates both the line clock and a coincidence signal applied to its output 19 . A first signal level (H) of the coincidence signal means that the horizontal phase control circuit 13 is in phase with the synchronizing signal component of the video signal, and a second signal level (L) indicates the non-in-phase state. A defined value for the phase difference between the sync signal component of the video signal and the line clock signal serves as the decision threshold.

The vertical pulse, the line clock signal and the Koinzi denzsignal are supplied to a device 11 , which generates a signal at its output 21 , the signal to which indicates whether the television set is supplied with an antenna signal via the antenna 1 or a video recorder output signal via the input connection 15 . The device 11 is followed by a control unit 12 with which control signals are generated, which are fed back into the vertical separation stage 8 and the horizontal synchronization device 9, respectively. The control unit 12 can, for example, carry out a signal amplification, a threshold decision or the timely validation of the control signals. With the feedback signals, the signal processing is adapted to the type of video signal source in each of the devices 8 and 9 , so that the video signal processing device is optimized. For example, the interference sensitivity can be reduced.

For example, the vertical impulse interference can be adapted to the video signal source in the vertical separation stage 8 . When the video signal is fed into the antenna, the vertical signal components can be disturbed by noise or attenuation in such a way that they can no longer be clearly derived from the video signal in the vertical separation stage 8 . It is then advisable to automatically derive the subsequent vertical pulse from the sequence of the preceding vertical pulses. Experience has shown that the number of lines in a video image fluctuates when feeding in a video recorder. Therefore, it makes sense to always derive the vertical pulse from the video signal without automatic vertical pulse generation being provided.

In the horizontal synchronization device 9 , it is geous before to adjust the time constant of the horizontal phase control circuit 13 to the type of video signal source. In the case of video recorder feed-in, a control time constant which is smaller in comparison to antenna operation is advantageous since the horizontal synchronization device 9 can then adjust more quickly to the line signals which are slightly phase-shifted with respect to one another. In antenna operation, a larger control time constant is more advantageous since the signal processing is then less sensitive to noise coupled into the transmission channel.

An embodiment of the device 11 is shown in FIG. 2. In the device 11 , the usual property of video recorders is evaluated, that in the area of the vertical blanking the sync signal pulses of the video signal compared to a clock signal with constant clock period each have a statistically distributed phase shift in a certain range. This is essentially caused by inaccuracies in the positioning of the reading device on the recording track running at an angle to the direction of the recording tape. The device 11 contains a device 30 , the output signal at a terminal 35 indicates the period of time during which the horizontal phase locked loop 13 was not locked until the occurrence of the vertical pulse.

The device 30 can be implemented by a counting device 33 and a storage device 34 connected downstream of it. As a counter 33 , for example, a forward / backward counter is used, the counting range of which is limited at the top. The forward / backward control input of the counter is connected to the output 19 of the horizontal phase control circuit 13 , which carries the coincidence signal, the clock input of the counter to the output 18 of the horizontal synchronization device 9 , which carries the line clock signal. The counter decrements with the line clock if the phase-locked loop has settled, otherwise the counter increments. The upper limit of the counting range prevents the counter reading from switching to zero status when fully controlled. The lower counting range limit prevents the corresponding switchover when the counter reading is zero. By the up / down counter for the device 11, a time delay is achieved such that the video recorder feed can only be recognized when the horizontal synchronization device is in a stable Arbeitszu state.

A latch is used as the storage device 34 , the sen input for the takeover pulse is connected to the terminal 20 of the vertical separation stage 8 , which carries the vertical pulse. The storage device 34 therefore takes over the current counter reading of the counting device 33 for each vertical pulse. The output of the storage device 34 is the output 35 of the device 30 .

The device 30 is followed by a device 31 with which a decision is made as to whether the value at the output 35 of the device 30 lies within a defined range. This determines whether the time period of the non-locked state of the horizontal phase locked loop lies in a defined range at the time of the occurrence of the vertical pulse. This range is to be set so that it corresponds to the typical phase jump that occurs in a video signal supplied by a video recorder between the synchronizing signal pulse and the line clock supplied by the horizontal phase-locked loop 13 in the area of the vertical blanking interval. The signal present at the output 36 of the device 31 assumes, for example, a first signal level value (H) if the value stored in the latch 34 lies within the defined range, otherwise a second signal level value (L).

In order to obtain a secure settling of the device 11 and a certain inertia towards short-term interference pulses, the device 31 is followed by a device 32 with a low-pass character. The device 32 can, for example, be designed as an up / down counter with upper and lower counting range limitation, the clock input of the counter being connected to the output 20 of the vertical separation stage 8 and the forward / reverse switching input of the counter being connected to the output 36 of the stage 31 . The counter counts up when the value stored in the latch 34 is recognized by the device 31 as being within the range, otherwise the counter counts down. The output signal at terminal 21 of device 11 is then switched active when the counter reading of counter 32 exceeds a predetermined threshold. Practically for this purpose, the connection 21 is connected to the most significant bit of the output of the counter 32 . Alternatively, a digital filter can be used for the device 32 . The filter is advantageously carried out in such a way that an average value is calculated from a series of successive values at the connection 36 .

The device according to the invention can be constructed with the hardware elements described and correspondingly switched in FIG . Alternatively, the device can also be implemented partially or entirely using a microprocessor with software control.

In FIG. 3, the time course is a series of in Figs. 1, 2 shown signals occurring. The Kur ve 40 shows a typical phase jump between the synchron signal portion of the video signal and the line clock signal generated by the horizontal synchronization device 9 , which arises when the video signal is fed in from a video recorder. The phase jump on the edge 41 is corrected in the further course of the curve 40 , so that the synchronous signal component and line clock are back in phase. The temporal course of the coincidence signal A, which is present at the output 19 of the horizontal phase locked loop 13 , shows an H level in the steady state of the phase locked loop and an L level 43 , while the phase difference between the synchronous signal component and the line clock signal is greater than the threshold 42 . The signal B at the output of the counter 33 is shown in the event that the counter 33 is an up / down counter with upper and lower range limit. In the L phase of signal A, that is, when the horizontal phase locked loop 13 does not coincide, the counter 33 is counted up, while the L phase of signal A counts down to the state zero. The signal C at the output 20 of the vertical separation stage 8 has a vertical pulse at the position 44 . The latch 34 is clocked with the vertical pulse, so that the counter value "3" is adopted for the signal D at its output 35 . In the present case, it is found that the value "3" stored in the latch 34 lies within the typical range for video recorder feed, so that the signal E is set from L to H ge. In the device 32 , a sequence of signals E, which are present in each case to successive vertical pulses 44 , can be low-pass filtered. The thus generated signal at terminal 21 is then used to control the signal processing in the devices 8 , 9 depending on the type of video signal source.

Claims (5)

1. Device for processing video signals divided into lines with a synchronous separation stage ( 7 ), through which a line-synchronous signal component is separated from the video signal, with a vertical separation stage ( 8 ), through which an image-synchronous vertical pulse is separated from the video signal, with a synchronization device ( 9 ) by which a line-synchronous clock signal is generated from the line-synchronous signal component of the video signal, and with a first device ( 11 ) by which a first signal for controlling the signal processing in the device is generated, which ver different signal values depending on of the type of video signal source, characterized in that the first device ( 11 ) has a second device ( 30 ) with which a second signal is generated by which the time period is specified, during which the line-synchronous clock signal and the line syn Chrone signal component of the video signal at the time of the vertical pulse it is not synchronous that the first Einrich device ( 11 ) has a third device ( 31 ), which is supplied with the second signal and by which a third signal is generated which takes a first signal value when the second signal in a specified range , and which takes a second signal value when the second signal is outside the specified range, and in that the first device ( 11 ) has a fourth device ( 32 ) with a low-pass character, to which the third signal is supplied and whose output signal is the first signal . 2. Apparatus according to claim 1, characterized in that the second device ( 30 ) contains an up / down counter ( 33 ) with an upper and a lower counting range limit that the clock input of the up / down counter is controlled by the line-synchronized clock signal that the The up / down switching input of the up / down counter is controlled by a signal generated by the synchronization device, which indicates whether the phase of the line-synchronous clock signal deviates from the line-synchronous signal component of the video signal by a predetermined amount, that the second device ( 30 ) has a memory device ( 34 ) contains that the input of the memory device is connected to an output of the up / down counter ( 33 ), that the clock input of the memory device is controlled by the vertical pulse and that the output ( 35 ) of the memory device carries the second signal. 3. Apparatus according to claim 1, characterized in that the fourth device ( 32 ) is a front up / down counter with an upper and lower counting range limit, the clock input is controlled by the vertical pulse and the forward / reverse switching input controlled by the third signal becomes. 4. Apparatus according to claim 1, characterized in that the fourth device ( 32 ) is a di gital filter, the clock input is controlled by the vertical pulse, the input is controlled by the third signal and the output ( 21 ) carries the first signal. 5. Apparatus according to claim 4, characterized records that with the digital filter of the tel value from a number of successive values of the third signal is formed.