JP2773863B2 - Video signal synthesizer - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video signal synthesizing apparatus, and in particular, a plurality of composite video signals are input simultaneously, and one of the input composite video signals is used as a main screen, The present invention relates to an apparatus for obtaining a composite video signal representing a composite screen inserted into a main screen with the remaining sub-screens being sub-screens. [Prior Art] FIG. 2 shows a video signal synthesizing device for obtaining a so-called picture-in-picture signal as a composite video signal, that is, a synthesized screen in which another sub-screen is inserted as a reduced screen with respect to a main screen. FIG. 2 is a block circuit diagram showing a conventional example of an apparatus for obtaining a composite video signal. This conventional example shows a case where there is one sub-screen. In FIG. 2, (11) is a first input terminal to which a first composite video signal (hereinafter, referred to as "main screen signal") (1) serving as a main screen is input, and (12) is a first YC. A separator, (13) a first chroma (color signal) demodulator, (14) a first synchronizing signal separator, and (15) a second composite video signal (hereinafter, referred to as a “sub-screen”) serving as a sub-screen. (2) is input, (16) is a second YC separator, (17) is a second chroma (color signal) demodulator, and (18) is a second Synchronous signal separators, (19), (20), and (21) are first, second, and third AD converters (analog-to-digital converters), (22), (2)
3) and (24) are the first, second, and third aspects in which writing and reading can be performed simultaneously and at mutually asynchronous timing.
Digital memory of (25), (26), (27) are the first and second
2, the third DA converter (digital / analog converter), (28) is an analog switch, (29) is a chroma modulator, (30) is a YC adder, (31) is an output terminal, (32), ( Three
3) are first and second digital signal processing controllers. Next, the operation will be described. The main screen signal (1) input from the first input terminal (11) is supplied to a first YC separator (12).
As a result, the signal is separated into a first luminance signal (34) and a first chrominance subcarrier signal (35). The first chrominance subcarrier signal (35) is demodulated by a first chroma demodulator (13) into a first red difference signal (36) and a first blue difference signal (37). On the other hand, the sub-screen signal (2) input from the second input terminal (15) is converted by the second YC separator (16) into the second luminance signal (38) and the second color sub-carrier signal ( 39). The second chrominance subcarrier signal (39) is demodulated by a second chroma demodulator (17) into a second red difference signal (40) and a second blue difference signal (41). First, second, and third AD converters (19), (20), (21)
Are the second luminance signal (38), the second red color difference signal (40),
The second blue difference signal (41) is converted into a digital signal, respectively, and the first, second, and third digital memories (22), (2)
Write to 3) and (24). At this time, the first and second control signals (42) and (43) required for the write control are generated by the first digital signal processing system controller (32). It is synchronized with the synchronization signal (44) separated by the signal separator (18), that is, synchronized with the sub-screen signal. Next, the first, second, and third digital memories (22),
When reading the contents from (23) and (24), the sub-screen is reduced, that is, compressed in the time direction. The compression in the time direction uses digital memories (22), (23),
The scanning speed of the content of (24) is k times (k>
1) can be realized, and as a result, a digital signal compressed to 1 / k in the time direction is obtained. The digital signal compressed in the time direction is converted into an analog signal by the first, second and third DA converters (25), (26) and (27). Through this digital signal processing system, the second luminance signal (38), the second red difference signal (40), and the second blue difference signal (41) are time-compressed into the third luminance signal (45). ), A third red color difference signal (46) and a third blue color difference signal (47). Here, the third and fourth control signals (4
8) and (49) are generated by the second digital signal processing system controller (33).
Is synchronized with the synchronizing signal (50) separated by the synchronizing signal separator (14), that is, with the main screen signal (1). Of course,
The obtained third luminance signal (45) and third red difference signal (4
6), the third blue difference signal (47) is also synchronized with this. The three analog switches (28) are connected to the main screen signal,
Used for time division multiplexing with time-compressed sub-screen signals,
Switching command signal (51) for this analog switch (28)
Is a timing synchronized with the main screen signal. Since the result of the time division multiplexing of the analog switch (28) is separated into a luminance signal, a red difference signal, and a blue difference signal, a chrominance subcarrier signal is generated in the chroma modulator (29) and then added. The target composite video signal (3) is obtained at the output terminal (31) by adding the luminance signal in the device (30). [Problems to be Solved by the Invention] Since the conventional video signal synthesizing apparatus is configured as described above, chroma demodulation and chroma modulation are also performed on the main screen signal (1) which does not need to perform time compression. This causes deterioration in image quality, and requires three analog switches for time division multiplexing, which is a significant cost factor when increasing the number of sub-screens. There was. SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and it is possible to eliminate the deterioration of the image quality of the main screen and to make the analog switch a single system regardless of the number of sub-screens.
It is an object of the present invention to obtain a video signal synthesizing device capable of reducing costs. [Means for Solving the Problems] A video signal synthesizing apparatus according to the present invention synthesizes a first composite video signal as a main screen and a second composite video signal as a sub-screen, and A separating means for separating the second composite video signal into a luminance signal, a red color difference signal, and a blue color difference signal; A time axis compression unit for compressing the separated luminance signal, red color difference signal, and blue color difference signal on the time axis, and a chroma modulation unit for modulating the time axis compressed red difference signal and blue color difference signal to generate a color subcarrier signal; Adding means for adding the color sub-carrier signal and the time-axis-compressed luminance signal to create a third composite video signal; and a phase of a third color burst signal extracted from the color sub-carrier signal and First composite movie A phase detection unit that compares a phase of the first color burst signal extracted from the color subcarrier signal of the image signal and outputs a signal corresponding to the phase difference; and outputs the first color burst signal based on an output of the phase detection unit. Synchronized with the phase of the color burst signal of
A carrier generating means for generating the first and second carrier signals having a phase difference of 90 degrees, and a time-division multiplexing of the first composite video signal and the third composite video signal to produce the composite composite video A switch means for outputting a signal, forming a phase-locked loop including the phase detection means, the carrier wave generation means, and the chroma modulation means.
It is configured such that chroma modulation in the chroma modulation means is performed based on a second carrier signal. [Operation] In the video signal synthesizing apparatus according to the present invention, since the above-described configuration is employed, when re-modulating the sub-screen, the carrier required for the chroma modulation circuit of the sub-screen is synchronized with the color burst signal of the main screen. The main screen and the sub-screen can be time-division multiplexed in the state of a composite video signal, and the processing related to chroma demodulation and chroma modulation of the main screen is unnecessary. In addition, since the color burst signals of the main screen and the sub-screen are synchronized, no hue shift occurs between the main screen and the sub-screen. Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of one embodiment of the present invention, and the same reference numerals as those in FIG. 2 denote the same parts. In the figure,
(52) is a first color burst signal for removing the color burst signal (59) of the main picture signal (1) from the first color sub-carrier signal (35) separated by the first YC separator (12). Stripping circuit, (53) is a phase detector, (54) is a voltage controlled oscillator (hereinafter referred to as “VCO”), (55) and (56) are VCO (5
(57) is a second color burst signal stripping circuit, (70) is a reduced sub-screen signal generation circuit, and a second YC Separator (16), second chroma demodulator (17), second sync separator (18), AD converters (19), (20), (21), digital memories (22), (23), (24), DA converters (25), (26), (27), chroma modulator (29), adder (30), and first digital processing controller (3
It consists of 2). (58) is a third composite video signal representing the reduced sub-screen (hereinafter, referred to as “reduced sub-screen signal”). In addition, the first color burst signal stripping circuit (5
2), phase detector (53), VCO (54), second color burst signal stripping circuit (57), and chroma modulator (29)
Forms a phase locked loop circuit (PLL circuit) (80). Next, the operation will be described. The VCO (54) is automatically adjusted by the voltage signal (61) input from the phase detector (53) so as to always synchronize with the same phase at the same frequency as the first color burst signal (59), and It generates first and second carrier signals having a phase difference of 90 ° from each other. The chroma modulator (29) is read from the second and third digital memories (23) and (24) and converted into an analog signal by the second and third DA converters (26) and (27). The third red color difference signal (46) and the third blue color difference signal (4
7) are modulated by the first and second carrier signals (55) and (56) to generate a third color sub-carrier signal. Adder (3
0) is the third chrominance subcarrier signal and the third luminance signal (4
5) is added to output a third composite video signal (hereinafter, referred to as a "reduced sub-screen signal") (58) representing the reduced screen. The analog switch (28) performs time-division multiplexing of the main signal (1) and the reduced sub-screen signal (58) and outputs a composite video signal (3) representing a composite screen at an output terminal (31). In the above configuration, the first burst signal stripping circuit (5
2), phase detector (53), VCO (54), chroma modulator (2
9) and the signal circuit circulating in the second burst stripping circuit (57) form a phase locked loop, and therefore the third circuit included in the color subcarrier signal of the reduced subscreen signal (58). Is automatically adjusted to always match the frequency and phase of the first color burst signal (59). Therefore, even when time-division multiplexing is performed by a single analog switch (28), the color burst signals of the main screen signal (1) and the reduced sub-screen signal (58) match, so that the main screen and the reduced sub-screen signal are identical. No hue shift of the screen occurs. In the above embodiment, the sub-screen signal (2) to be synthesized is
Is shown for one sub-screen, the number of sub-screens may be two or more. In this case, the reduced sub-screen signal generation circuits (70) in the embodiment are provided by the number of sub-screens and the second burst An arbitrary one of the sub-screen signals (58) is connected to the signal stripping circuit (57) on behalf of each of the control signals (48),
(49). (51) and the first and second carrier signals (55),
(56) may be a carrier signal common to the sub-screen signal generation circuits (70), and the number of input terminals of the analog switch (28) may be increased. [Effects of the Invention] As described above, according to the video signal synthesizing apparatus according to the present invention, the first composite video signal serving as the main screen and the second composite video signal serving as the sub-screen are synthesized, and the main In a video signal synthesizing apparatus for generating a composite composite video signal in which a reduced sub-screen is inserted in a screen, separating means for separating the second composite video signal into a luminance signal, a red difference signal, and a blue difference signal And a time axis compression means for time axis compressing the separated luminance signal, red color difference signal and blue color difference signal respectively, and chroma modulation for modulating the time axis compressed red and blue color difference signals to generate a color subcarrier signal Means for adding a color subcarrier signal and the time-base compressed luminance signal to form a third composite video signal; and a phase of a third color burst signal extracted from the color subcarrier signal And the first
Phase detection means for comparing the phase of the first color burst signal extracted from the color sub-carrier signal of the composite video signal, and outputting a signal corresponding to the phase difference, based on the output of the phase detection means, Carrier generating means for generating the first and second carrier signals which are synchronized with the phase of the first color burst signal and have a phase difference of 90 degrees from each other, the first composite video signal and the third Switch means for time-division multiplexing the composite video signal and outputting the composite video signal, forming a phase-locked loop including the phase detection means, carrier generation means, and chroma modulation means, Since the chroma modulation in the chroma modulating means is performed based on the first and second carrier signals generated in the above, the phase of the color burst signal of the main screen and the phase of the sub-screen automatically match. In other words, the main and sub-screens can be time-division multiplexed in the state of the composite video signal while the hues always match, thereby eliminating the need for chroma demodulation and chroma modulation for the main screen. In addition, there is an effect that the cost of the entire system can be reduced while preventing deterioration of the image quality of the main screen.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block circuit diagram showing an example of a video signal synthesizing device according to the present invention, and FIG. 2 is a block circuit diagram of a conventional video signal synthesizing device. (28)… Analog switch, (53)… Phase detector,
(54): Voltage-controlled oscillator, (70): Reduced sub-screen signal generation circuit, (80): Phase-locked loop circuit. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (1)

(57) [Claims] A video signal for synthesizing a first composite video signal serving as a main screen and a second composite video signal serving as a sub-screen to create a combined composite video signal having a reduced sub-screen inserted in the main screen In the synthesizing device, separating means for separating the second composite video signal into a luminance signal, a red difference signal, and a blue difference signal, and a time for compressing the separated luminance signal, red difference signal, and blue difference signal on a time axis. Axis compression means, chroma modulation means for modulating the time-axis-compressed red difference signal and blue difference signal to generate a color subcarrier signal, and adding the color subcarrier signal and the time-axis-compressed luminance signal. Adding means for generating a third composite video signal; a phase of a third color burst signal extracted from the color subcarrier signal; and a first color burst signal extracted from the color subcarrier signal of the first composite video signal. of Phase detecting means for comparing the phase with the phase of the first color burst signal and outputting a signal corresponding to the phase difference based on the output of the phase detecting means, and a phase difference of 90 degrees from each other. Carrier generating means for generating first and second carrier signals having a phase difference; and a switch for time-division multiplexing the first composite video signal and the third composite video signal and outputting the composite composite video signal Means for forming a phase-locked loop including the phase detecting means, the carrier wave generating means, and the chroma modulating means, and the chroma modulating means based on the first and second carrier signals generated by the carrier wave generating means. A video signal synthesizing device, which is configured to perform modulation.