JPS625510B2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a video encryption processing method for television, and in particular, in order to provide independent programs for a fee, the present invention encrypts the video signal by inverting the video signal using an encoder at the broadcasting station side. A video encryption processing method used in wireless pay television broadcasting in which a television signal is sent out, and a specific subscriber decodes the encrypted television signal using a decoder and restores it to his or her own television receiver. Regarding improvements.

A wireless pay television system called the pay television system is a system that offers a wide variety of programs even for a fee, in response to the annoying commercials and deterioration in the quality of programs due to various restrictions caused by free commercial broadcasting. It was created and developed based on the demand for a wireless system, and has the advantages of being wireless, which saves the cost and time of laying cables, and there is no limit to the number of subscribers per system. Because of this, its future potential is attracting attention.

Generally, wireless pay television systems target only specific subscribers, and the television and audio signals are encrypted to exclude non-subscribers. Among these, a conventional video signal encryption method is shown in FIG. The video signal supplied to the input terminal 1 has its polarity inverted by the video polarity inverter 3 and is output to the output terminal 2. At that time, the video polarity inverter 3 is controlled by the random number signal generator 4, that is, the video polarity inverter 3
Then, the polarity of the input video signal as shown in FIG. 2A is inverted as shown in FIG. 2B, or is output without being inverted. The decoder is capable of decoding and restoring the encrypted video signal based on a key code signal prepared in advance, and is therefore configured so that only a specific subscriber having the decoder can view the video signal.

In this conventional video signal encryption method, when the video signal that has been inverted and transmitted by the broadcasting station's encoder is restored by the subscriber's decoder, the components used in the encoder and decoder If a discrepancy occurs between the original video signal and the video signal restored on the subscriber side due to differences in the characteristics (linearity, etc.) of devices (diodes, transistors, etc.), irregular brightness or hue may occur. This causes screen flickering due to changes such as In order to eliminate this drawback, it is not desirable from the viewpoint of manufacturing or economics to make the characteristics of the parts used in the encoder and decoder the same or to perform strict adjustment and maintenance.

Accordingly, an object of the present invention is to provide a video encryption processing method that can eliminate the drawbacks such as flickering of the screen without increasing the cost.

It is well known that video signals from television and the like are subject to a so-called ergodic process in which adjacent fields exhibit a strong correlation, excluding changes in scene due to camera cuts and the like.

Naturally, therefore, this property collapses when the scene changes.

Focusing on this point, the present invention determines the correlation between the frames through arithmetic processing, detects the moment of scene change, and controls the reversal or non-reversal of the scene to visually check the effects of flicker. This reduces the

The present invention will be described in detail below with reference to Examples. FIG. 3 shows one field of a television video signal. It is well known that even within one field, video signals have strong autocorrelation in the horizontal and vertical directions. Therefore, from a to p in Figure 3
Even by just sampling at intervals such as the points shown above, it is possible to know the characteristics of the field. At least, this is sufficient to know the strength of the correlation between each field.

A specific embodiment of the present invention based on the above idea is shown in FIG.

In the figure, 1 is a low-pass filter, 2 is a sample and hold circuit, 3 is an A-D converter, 4 is a register, 5 and 6 are buffer registers, 7 is a coincidence detection circuit, 8 is an AND gate, 9 is a counter, 10
1 is a comparator, 11 is an inverter, 12 is an AND gate, and 13 is a flip-flop circuit.

The video signal _S1 is first reduced in resolution by a low pass filter. This is to average the amount of change in brightness during the sampling period. Next, by giving the output of the low-pass filter / to the sample-and-hold circuit 2, each point from a to p in FIG. . This A/D conversion is 3
A level of about 8 bits is sufficient. The A/D converted video signal data at each point is input to the register 4 and at the same time is taken into the buffer register 6. Also, the output of register 4 is the video signal data of the same point one field ago,
It is input to the buffer register 5. The values of the buffer registers 5 and 6 are checked by a match detection circuit 7, and if they match, ₁ is added to a counter 9 through an AND gate 8 to which a strobe signal st1 is applied. In this way, it is possible to find out how many points from a to p of an arbitrary field and the previous field match. Investigate in advance whether it is appropriate to consider autocorrelation when these points match,
Let the threshold value be SH.

The output of the counter 9 and the threshold value SH are inputted to a comparator 10 for comparison, and the output is passed through an inverter 11 to which a strobe signal st ₂ is applied to determine whether or not there is an autocorrelation (scene change). The state of the flip-flop circuit 13 is inverted or not inverted. The output of the flip-flop circuit 13 is used as an inverted/non-inverted control signal C for encoding the video signal.

As is clear from the above explanation, according to the present invention, at least a part of the video signal is inverted and transmitted by the encoder at the broadcasting station side, and the video signal received by a specific subscriber is In a video encryption processing method used for television broadcasting that is restored and viewed via a decoder, the correlation between each field of the video signal is investigated through arithmetic processing, and the moment when the correlation becomes weak is detected by a program. In the case of the source, it is judged that it is time to switch, and the encryption operation of the video signal is controlled, so switching between inversion and non-inversion becomes less noticeable, and defects such as screen flickering can be easily resolved without increasing costs. Can be removed.

[Brief explanation of the drawing]

Figure 1 is a block diagram showing a conventional video encryption system. Figure 2 A and B are waveform diagrams illustrating inversion and non-inversion operations of a video signal. Figure 3 illustrates sample points in one field of a television signal. figure to do,
FIG. 4 is a block diagram showing one embodiment of the present invention. 1...Low pass filter, 2...Sample hold circuit, 3...A-D converter, 4...Register, 5, 6...
Buffer register, 7... Match detection circuit, 9... Counter, 10... Comparator, 13... Flip-flop circuit.

Claims (1)

[Claims] 1. A broadcasting station transmits an encrypted video signal obtained by inverting and encrypting at least a portion of a video signal, and a specific subscriber receives the encrypted video signal and restores it using a decoder for viewing. In a television broadcasting system, an arithmetic processing means is provided to detect the correlation between each field of the video signal, and the moment when the correlation becomes weak is determined as the time of scene change of the video signal, and the encryption of the video signal is performed. A video encryption processing method characterized by controlling inversion and non-inversion operations.