NL192654C - Video receiver device suitable for multi-channel reception in a menu-operated multi-channel display device with a picture-in-picture function. - Google Patents

Description

1 192654

Video receiver device suitable for multi-channel reception in a menu-operated multi-channel display device with a picture-in-picture function

The invention relates to a video receiving device suitable for multi-channel reception in a menu-operated multi-channel display device with a picture-in-picture function, comprising first tuning means and second tuning means for receiving broadcast signals and separating the channel signals in the respective broadcast signals; selection means for selecting sub-screens; video recorder signal processing means for processing a display signal of a video recorder and a main picture signal and for outputting screen signals; and picture-in-picture function processing means with input screen signals from the video recorder signal processing means and from said sub-screen selection means for outputting picture-in-picture multi-screen signals, wherein the multi-channel display device comprises a first selection device for selecting one of the output signals of the first or second tuning means or a line input signal and outputting a main picture signal; the sub screen selection means selects a signal other than the selected signal and outputs this signal as a sub screen signal; the multi-channel display device comprises control means for controlling the output selections of the tuning means and the image processing of the picture-in-picture processing means. Such a video receiver is described in the older, non-prepublished EP patent application 0.377.334.

The object of the present invention is to provide a video-receiving device of the above-described type, which, with a simple menu-operated browsing of the channels to be displayed, only shows those channels which are qualitatively good to receive.

This is accomplished with the video receiving device in that the multi-channel display device includes means for sequentially performing the following steps: sequentially scanning channel data stored in a skip memory of the control means to distinguish channel signals with a synchronization signal; and selecting the distinct channels corresponding to the number of channels suitable for display on sub screens and displaying the selected channels on the sub screens.

The invention will now be explained in more detail with reference to the drawing consisting of the following figures.

Figures 1— (A) and (B) are the waveforms for the PIP and the tuning for the exemplary multichannel embodiment of the present invention; Figure 1— (C) is the channel display corresponding to the location of the skip memory; Figures 1— (D) and (E) are the status diagram of the multi-channel display shown in a main screen; Figures 2— (A) and (B) are multichannel flicker time map and reference time map; Figures 3- (A), (B), (C) and (D) are flicker maps of the screen with division of the skip memory into pages; 40 Figures 4— (A-1), (A-2), (B-1) and (B-2) are the display screen for the main screen and the sub screen of tuner 1 and tuner 2; Figures 5- (A), (-1), (B) and B-1) are device block diagrams of the tuner 1 and the tuner 2, respectively; Figure 6 is the overall multichannel device block diagram according to the invention; and Figure 7 is a flowchart for multichannel operation according to the invention.

Reference numerals in the drawing 501: t.v. tuning circuit 502, 512: signal processing circuit of the VTR 50 503, 513: switching section 504, 514: PIP processing circuit 510: input selector of the main screen 511: output selector of the sub-screen 600: micro-computer 55 610: OSD IC (on-screen display integrated circuit ) 620: mixer 630: audio circuit 192654 2 640: multiplexer 650: tuner 1 660: tuner 2

Multichannel mode is defined as n PIP displays within a main screen, where the screen data of the PIP sub-screens is always extracted from a skip memory and simultaneously displayed on these n PIP sub-screens.

The multichannel mode can operate on the PIP system apart from tuner 1 and tuner 2. In the case of multichannel mode, the method of the PIP control is as follows. When the multichannel button is on, multichannel mode starts working.

When there is a synchronized signal on a skip channel during a multichannel mode, the channel becomes an active channel as shown in Figure 1- (A). In Figure 1- (A), (x) is the rotate data output of the PIP, (1) still data output of the PIP, (2) rotated data output of the rotate data output, (3) an output starting at channel selection of the tuner, (4) AFT (Auto Fine Tuning) processing a completion of the tuner that occurs after tuning, and (5) 15 PIP still data output (same as 1) that is still cancels.

Therefore, the first standstill means a standstill and the second standstill means a standstill cancellation. It is assumed that channels K to N are stored in the skip memory.

When there is no synchronized signal in multi mode, the channel becomes an inactive channel.

In Figures 1- (B), 1 'to 3' do the same function as 1 to 3 in Figures 1- (A), 4 'is an output signal for determining no synchronized signal, 5' is an output signal that jumps to a corresponding channel, 6 'is an output signal for repeating the processes from 1' to 5 'until it finds the channel position that has a synchronized signal, and 7' performs the method of Figure 1— ( A) off when a synchronized signal is found.

Thus, the channel stored in the skip memory becomes active as shown in Figure 1— (C), assuming that an unadded channel exists in position 3 and an inactive channel exists in position 4. The unaddressed channel is defined as a channel not previously stored in the skip memory.

The entire screen obtained by the operation of Figure 1— (B) represents the display of channel O, as indicated in Figure 1— (D), where the channel (N-channel) that does not have a synchronized signal of Figure 1- (A) is skipped.

When there is a specific channel key in the operating mode of Figure 1- (E), the pressed channel mode works.

Figure 2 shows the waveform making the flicker time of the multi-channel up / down. Figure 2- (A) shows the time increment (t) setting using the (+) key and (-) key when one channel is skipped for another channel.

Figure 2- (B) shows the method of making the flicker time up / down by 0.2 seconds per step when the reference time of this changed time (t) is 1 second.

Figure 3 illustrates a page up / down operation when the multichannel key is on.

40 Figure 3- (A) shows a skip memory consisting of 32 places. Figure 3- (B) shows a page of the TV screen why four channels corresponding to 4 locations on the skip memory are displayed when the multichannel is on.

Therefore, when a page is defined to display four places per page, it is possible that they are PIP pages in the skip memory (4xP = 4P).

45 It was assumed in Figure 3— (A) that position 4 and position 6 are non-added channels, and position 3 and position 10 are inactive channels without a synchronized signal. In the case of Figure 3- (B), each of the four channels correspond to four locations of the skip memory displayed on a page of a TV screen, and it is possible to scroll the display up or down with a page .

The arrow in Figure 3- (B) indicates the direction of flicker progression along each channel.

50 Figure 3- (C) shows the progress of this page up / down display. Figure 3- (D) shows the channels added to the skip memory.

When there are channels that do not have synchronous signals, the channel selector jumps over the channels. Thus, a multi-channel mode is accomplished by the position with synchronous signals. As an example, when position 3 is an inactive channel that does not have a synchronous channel, channel 55 is skipped and an active channel becomes active.

Figure 4 shows that more channels are displayed on a single screen.

Figure 4- (A-1) shows that a main screen is a playback screen (PB screen) and a multichannel 3 192654 screen when the tuner 1 is in the playback mode.

Figure 4- (A-2) describes the TV screen on which the main screen is a blue screen that does not receive a broadcast signal and the sub screens are multi-channel screens when the TV is turned on, but is not in playback mode.

5 Figure 4- (B-1) shows that the main screen is in playback mode and the sub screen in multi-channel mode when tuner 2 is in a playback mode.

Figure 4 ~ (B-2) shows that when there is a sync signal in a main screen but it is not in the playback mode, the main screen shows tuner 1 or a single line and the sub screen shows tuner 2.

Figure 5- (A) is the tuner-1 system and Figure 5- (B) is the tuner-2 system.

Tuner-1 system consists of tuner circuit (501) in the TV, signal processing circuit (502) for VTR, switch section (503) that chooses the blue screen signal which channel does not receive a broadcast signal, and is controlled by a main screen control signal (Q7) and the sub-screen (Q6), and the PIP block (Picture-ln-Picture) (504) for controlling PIP.

15 Tuner-2 system consists of the main screen input selector (510), the sub screen output selector (511), the signal processing block (512) for VTR, the switching part (513) which chooses the blue screen and is controlled by a control signal for the main screen (Q7) and the sub screen (Q6) and the PIP block (514) for processing them in PIP mode.

Figures 5- (A-1) and 5- (B-1) describe the operation of tuner-1 and tuner-2 systems. "X" means a normal state that has a synchronous signal and "Y" indicates the inactive channel that has no synchronous signal.

In the example of Figure 5- (B-1), Q6 becomes L (low) for the first time and chooses the PB screen as the main screen in PB mode.

Q7 sets "X" to L with a synchronous signal and selects the received channel as a split screen.

25 If there is no synchronous signal, Q7 sets "Y" to H (high) and selects the blue screen as the sub screen.

Then, in the non-PB mode, Q6 and Q7 each select the received channel or the blue channel as the main screen or sub screen according to the existence of a synchronous signal.

Figure 6 shows the whole system composed of tuning unit 1 and tuning unit 2 of Figures 5 and 30 using a microcomputer as a control instrument.

Figure 7 is a flow switch for the system of Figure 6.

If the microcomputer (600) received a channel input (step 701), it makes a decision about whether the channel is from tuner 1 system or tuner 2 (step 704). When the tuner channel is 1, this will determine whether the channel is in a PB mode or not (step 705).

35 If it is in a PB mode, it chooses the PB screen as the main screen (step 706). When not in a PB mode, it chooses the blue screen as the main screen (707). If the tuner system is tuner 2, this will determine whether the subject mode is a PB mode or not (step 708). When it is a PB mode, it chooses the PB screen as the main screen (step 706). If it is not a PB mode, this will determine whether it is a main screen or a split screen (step 710).

40 If it is a main screen, it will check for the presence of a synchronous signal (step 711). If there is no synchronous signal, it selects the blue screen as the main screen (step 712). When the signal is a split screen (step 710), it again reverses the mode of main / split screen (step 713) and selects a main screen according to the input type; tuner 1, tuner 2 or LINE (step 714).

45 When the input is tuner 1, set the controller Q2 to H (step 715) and adjust the tuner 1 (step 716).

When the input is tuner 2, adjust the controller Q2 to low (step 717) and adjust tuner 2 (step 718).

When the input is LINE, the controller maintains the previous state of Q2 (step 719) and does nothing 50 for control (step 720).

When a main screen is selected according to the above method, the controller selects the blue screen as the main screen (step 722) according to the existence of a synchronous signal (step 721).

On the other hand, a selection of the sub screen is determined according to the state of the output selector, whether it is tuner 1 or tuner 2 or LINE (step 725).

55 When the output selector is tuner 1, the controller sets the signal Q2 to high (step 726), and adjusts tuner 1 (step 727). When it is the tuner 2, the controller sets the signal Q2 to low (step 728), and adjusts the tuner 2 (step 729).

Claims (3)

192654 4 When it is LINE, the controller maintains its previous state Q2 (step 730) and does nothing for checking (step 731) Sub-screen selection is completed according to the above method. The microcomputer performs the multichannel screen according to screen 1, 2 or n (step 732), performs the PIP 5 still and rotate key data (step 733), starts the selection of a tuner, performs the AFT action and performs then reset the PIP still data (step 734). The microcomputer makes a decision on the presence of a synchronous signal on the cameo (step 735). If there is no synchronous signal, the controller jumps to the next position (step 736). If there is a synchronous signal, the flicker is confirmed to end, and not (step 736-1) controller executes the flickering in progress (step 737), increases the page counter content (step 739 ) when the page is up (step 738), decreases the contents of the page counter (step 741) when the page is down (step 740), and makes a decision about the existence of a multi-channel input (step 742), that is re-entered. When there is an input, the multichannel is turned off (step 743) and the multichannel goes to the state prior to ON (step 745). When there is no multi-channel key input and there is a remocon channel key input (step 746), a corresponding channel is displayed on the corresponding screen (step 747). Therefore, according to the invention, the TV screen is changed to the state of a multi-channel display by using an existing PIP or multi-screen function and the effect of improving the convenience and reliability when using a TV system is obtained so that a user can easily choose his favorite channel by making it possible to select it with a menu type channel selection. 25 Conclusion 1. Video receiving device suitable for multi-channel reception in a menu-operated multi-channel display device with a picture-in-picture function, comprising first tuning means and second tuning means for receiving broadcast signals and separating channel signals in the respective broadcast signals; selection means for selecting subscreens; video recorder signal processing means for processing a display signal of a video recorder and the main picture signal and for outputting screen signals; and picture-in-picture function processing means with input screen signals from the video recorder signal processing means and from said sub-screen selection means for outputting picture-in-picture multi-screen signals; wherein the multi-channel display device comprises a first selection device for selecting one of the output signals of the first or second tuning means or a line input signal and for outputting a main picture signal; the sub-screen selection means selects a signal other than the selected signal and outputs this signal as a sub-screen signal; the multi-channel display device, and control means for controlling the output selections of the tuning means and of the picture-processing of the picture-in-picture processing means; characterized in that the multi-channel display device comprises means for sequentially performing the following steps: sequentially scanning channel data stored in a skip memory (Figure 3A) of the control means to distinguish channel signals with a sync signal (step 735) ; 45 selecting the distinct channels corresponding to the number of channels suitable for display on sub screens and displaying the selected channels on the sub screens. Hereby 10 sheets drawing