JPH044797B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a receiver for image signals that have been subjected to band compression processing, and more specifically, to reduce the signal bandwidth by multiplex sub-Nyquist sampling and to reduce the signal bandwidth between image frames. The present invention relates to a television signal receiving apparatus in which the amount of movement in a band is transmitted as a motion vector signal, and a control signal for controlling a decoding circuit when decoding a band-compressed image signal is transmitted together with the image signal.

Conventional technology A method of reducing the signal bandwidth by sub-Nyquist sampling when transmitting a wideband image signal such as a high-definition television signal (Television Society technical report material "Satellite one-channel transmission method for high-definition television") TEBS95-2, Vol7,
No. 44) is proposed. This method is called a motion-compensated multiple sub-Nyquist sampling transmission method, and the sampling phase is offset between fields, frames, and lines, and processing is performed such that the sampling phase goes around in four fields. The receiving side is equipped with a frame memory to store the image signals sequentially transmitted over four fields, and combines them to restore the television image. In a television that performs 2:1 interlaced scanning, the above-mentioned interframe offset subsampling processing and signal restoration processing are the basics.

In the method of transmitting image signals by performing inter-field and inter-frame offset subsampling processing, the complex circuit for receiving this signal and reproducing the television image tends to be complex, and the band compression processing In practice, it is difficult to completely detect moving parts of an image from among the image signals that have been subjected to this process. Therefore, it is effective to transmit an auxiliary signal to simplify the configuration of the decoding circuit, that is, a control signal for the receiving device together with the image signal. It is characterized by transmitting various control signals, such as control signals for interpolation processing in .

As shown in FIG. 2, a receiving device for decoding a band-compressed image signal using the above-mentioned control signal,
After the analog image signal supplied to the signal input terminal _T1 is converted into a digital signal by the A/D converter 10, the image signals sequentially received over four fields are stored in the memory () 20, and the image signals are stored between frames. After performing interpolation processing, the first signal processing circuit 30 performs predetermined processing, such as filter processing, on the interframe interpolation signal sent from the memory (I) 20, and then supplies the signal to the synthesis circuit 40. configured to do so. This first signal processing system can effectively decode the still part of the band-compressed image signal. The signal output from the A/D converter 10 described above is subjected to predetermined processing within the field, for example, filter processing, by the second signal processing circuit 50, and then sent to the synthesis circuit 40, where the signal is subjected to the second signal processing circuit 50. The system can effectively decode moving parts of band-compressed image signals. Since the output signals of these first and second signal processing systems are valid only for a still part and a moving part, respectively, the combining circuit 40 uses a moving part detector 60 and the still part of the image is processed by the first signal processing circuit. 30, and for moving parts, the output of the second signal processing circuit 50 is appropriately selected or combined. The output signal of the synthesis circuit 40 is subjected to inter-field interpolation processing by the memory ( ) 70 and the third signal processing circuit 80, and is sent to the signal output terminal _T2 via the D/A converter 90.

On the other hand, the control signal detector 100 is connected to the A/D converter 1
All control signals to be transmitted, such as motion vector signals, motion detection circuit control signals, and field interpolation control signals, are detected from among the signals from 0, and are sent to the memory (I) via conductors 101, 102, and 103, respectively.
20, motion part detector 60, third signal processing circuit 8
0. The motion vector signal is a signal that indicates the amount of movement of an image between frames with respect to uniform screen movement such as camera panning or tilting when performing interframe interpolation processing in the memory (I) 20. When the signal is transmitted, the memory (I) 20 shifts the position of the already stored signal of the previous frame vertically, horizontally, or diagonally, and then performs interframe interpolation. Therefore, the memory (I) where interpolation processing was performed between frames
The output signal of 20 removes image motion between frames. Moving part detector 60 from the conductor 102
The motion detection circuit control signal supplied to the motion detector 60 directly or indirectly changes the amount of motion for the pixel detected by the motion part detector 60, and performs the synthesis of the first and second signal processing circuits supplied to the synthesis circuit 40. Change the ratio. Therefore, for special camera work such as scene change or zooming, the synthesis circuit 40 includes information such that all outputs of the second signal processing circuit 50 are selected. The field interpolation control signal supplied to the third signal processing circuit 80 via the conductor 103 prohibits the operation of the third signal processing circuit which obtains interpolation signals from information at different positions in scanning and performs field interpolation processing. The operating conditions are set so that it will not be prohibited only if it is a completely still image or has a large number of still parts, and it will be set to be prohibited if the above-mentioned motion vector signal is transmitted. .

Problems to be Solved by the Invention In the known device for receiving a band-compressed image signal as described above, there are cases where it is desired to temporarily or continuously maintain the operation of the device, that is, freeze the image. This purpose can be achieved by stopping the writing of new signals to the memory (I) 20, but in known receiving devices, even if images are frozen by a predetermined means, they are transmitted sequentially. Since the moving part detector 60 and the third signal processing circuit 80 are controlled by the control signal, there is a problem that the image quality of the frozen image deteriorates.

SUMMARY OF THE INVENTION An object of the present invention is to provide a band-compressed image signal receiving device that can prevent deterioration in image quality when images are frozen.

Means for Solving the Problems A receiving device according to the present invention includes a first interpolation processing circuit for performing interframe interpolation of a band-compressed image signal, and a moving portion detector for detecting a moving portion of an image. , the second to perform inter-field interpolation
a signal processing circuit, a control signal detector for detecting a control signal transmitted together with the image signal, and a first control for controlling changes in the storage contents of a storage means which the first interpolation processing circuit has. and a control signal detector or a second control means for controlling the transmission of the output signal of the detector to the next stage.
The present invention is characterized in that the second control means and the second control means are configured to operate in conjunction with each other.

Effect The first control means arranged according to the present invention is the first control means arranged by the present invention.
In the normal state, the interpolation processing circuit performs interframe interpolation processing based on control signals sequentially transmitted from the transmitting side for each field, and the first interpolation processing circuit is activated by a predetermined operation. The image content to be output is controlled to be in a constant state, that is, to be frozen. The second control means is a control signal detector which supplies first, second, and third control signals to at least a first interpolation processing circuit, a motion part detector, and a second interpolation processing circuit, respectively, or an output signal thereof. It is connected to the supply line to the next stage, and under normal conditions, the control signal is transmitted sequentially from the transmitting side to each field, and the control signal detector sends out the control signal. Control is performed to change or fix the state of the third control signal.

Embodiments Examples of the present invention will be described below with reference to the drawings. In FIG. 1, an analog signal supplied to a signal input terminal _T1 is converted into a digital signal by an A/D converter 10, and then a switch (SW) 20
5 and a control signal detector 100, respectively. In the standard state, this SW 205 selects the output signal of the A/D converter 10 and supplies it to the memory 201, the second signal processing circuit 50, and one input terminal of the SW 206, respectively. The memory 201 delays the input signal from the SW 205 by about one field and supplies it to the next stage memory 202 . This memory 202
Similarly to the memory 201 described above, the memory 202 also has a delay time of about one field, so the output signal of the memory 202 is delayed by one frame from the incoming input signal.
Memories 203 and 204 are also similar to the aforementioned memory 20.
It performs the same processing as No. 1,204. Therefore, the current field and the previous frame signal are supplied to the SW 206, and this SW 206 performs frame interpolation by its signal switching action, and the conductor 20
The signal is sent to the first signal processing circuit 30 via 7.

The aforementioned memories 202 and 204 are supplied with a motion vector signal from the control signal detector 100 via the SW 103, and these memories are controlled in the vertical and horizontal directions of the image by the motion vector signal transmitted from the transmission side. Motion correction is performed by changing the delay time for the previous frame and sending a signal one frame earlier to the SW 206. Therefore SW103
are short-circuited in a standard state and supply the signal of conductor 101 to memories 202 and 204, respectively.

The output of the memory 204 is input to the other SW 205 described above, and is also input to the motion part detector 60. This moving part detector 60 includes an SW 205
An image signal is also supplied from the second signal processing circuit 50, which is supplied with the output signal of , and a moving portion of the image is detected from the difference between the image signals of the current field and two frames before. Furthermore, a conductor 10 is connected to the moving part detector 60 from the control signal detector 100.
2 and SW104, a signal is supplied to control the detection operation. For example, for special camera work such as detection sensitivity control or zooming, this control signal from the transmitting side is used to control the detection operation of the detector. 100 is controlled such that all images are determined to be moving, regardless of the presence or absence of still parts of the image. Therefore, in the standard state, the SW 104 is maintained in a short-circuited state.

The synthesis circuit 40 inputs the frame interpolation image signal supplied via the conductor 207 and the first signal processing circuit 30 and the image signal subjected to predetermined filter processing by the second signal processing circuit 50. The combination ratio of these two image signals is controlled by a control signal that is the output of the motion part detector.

The memory 70 and the third signal processing circuit 80 perform interpolation processing between fields of the image signal. Here, the third signal processing circuit 80 includes a control signal detector 100.
A control signal is supplied via a conductor 103 and a switch 105. This control signal is used when a motion vector is transmitted and motion compensation is performed,
This signal is used to inhibit field interpolation when there are many moving parts in the image, and this signal controls the interpolation process using the output image signal component delayed by approximately one field by the memory 70. .
Therefore, SW105 is short-circuited in the standard state. The D/A converter 90 sends out the restored wideband image signal to the signal output terminal _T2 .

In the receiving device according to the present invention having the above-described configuration, the SW20 is used for the purpose of freezing an image.
The aforementioned SWs 103 to 105 are controlled in conjunction with a known method in which the switch 5 continuously selects signals from the memory 204 and supplies them to the memory 201. These SWs are in standard condition as mentioned above, but SW
In conjunction with the operation of 205, the output control signals are changed or fixed to the same state as when receiving a still image by opening or predetermined logical processing. Therefore, neither memory 202 nor 204 is responsive to the motion vector signal that control signal detector 100 sends on conductor 101 and SW 20
6. Synthesizing circuit 40 via first signal processing circuit 30
An image signal that has been subjected to frame interpolation is supplied.
SW104 is opened in conjunction with SW205 or through predetermined logic processing, and the synthesis circuit 40 continuously connects either the first signal processing circuit 30 or the second signal processing circuit 50 with the signal output from the moving part detector 60 to the conductor 601. The motion part detector is not responsive to the control signal that the control signal detector 100 outputs on the conductor 102.

Motion part detector 60 regarding control of SW104
Which of the above two image signals is selected depends on the presence or absence of a motion vector signal between the field in question that freezes the image and the three fields transmitted prior to this field. That is, when a motion vector signal is being transmitted, the combining circuit 40 receives the image signal from the first signal processing circuit 30, and in the opposite case, the combining circuit 40 receives the image signal from the first signal processing circuit 30;
Preferably, the motion detector is controlled to select the image signal from the signal processing circuit 50.

The SW 105 is also controlled in conjunction with the SW 205 so that at least the third signal processing circuit 80 does not respond to a new control signal from the conducting wire 103. In this case, the third signal processing circuit 80 is controlled according to the state of the control signal transmitted to the field and sent out to the conducting wire 103. For example, if a signal that prohibits field interpolation is being transmitted, the third signal processing circuit 8 is configured to maintain this state.
Controls 0.

Effects of the Invention As described above, in the receiving device according to the present invention, a plurality of memories are connected in series for frame interpolation, and the image is frozen by circulating the image signals already stored in this memory. Since it controls the motion vector signal supplied to the memory, it has the feature that undesired motion correction operations are not performed. In addition, since the motion part detector and the signal processing circuit that performs interpolation processing between fields are fixed in a predetermined state in conjunction with image freezing processing, this has the excellent effect that the quality of frozen images does not deteriorate significantly. It is something.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a receiver for band-compressed image signals according to an embodiment of the present invention, and FIG. 2 is a block diagram of a conventional receiver for band-compressed image signals. 100... Control signal detector, 60... Motion part detector, 50... Second signal processing circuit, 40... Synthesizing circuit, 70... Memory, 30... First signal processing circuit, 80... Third signal processing circuit.

Claims (1)

[Claims] 1. A receiving device for a band-compressed image signal in which an image signal subjected to band-compressing processing using multiple sub-Nyquist sampling and a control signal for controlling the receiving device are multiplexed, and this device performs interframe interpolation. A first interpolation processing circuit for performing the
The first interpolation processing circuit includes at least a moving part detection circuit for detecting a moving part of an image and a control signal detection circuit for detecting the control signal, and the first interpolation processing circuit has a predetermined storage means and a control signal detection circuit for detecting the control signal. It has a first control means for holding the memory contents of the storage means and is configured to perform position correction on the previous frame image signal in response to a first control signal from the control signal detection circuit, In the band compressed image signal receiving device, the moving part detection circuit is configured such that its detection output signal is changed directly or indirectly in response to at least a second control signal from the control signal detection circuit. The control signal detection circuit sends the first and second control signals to the first interpolation processing circuit and the moving portion detection circuit via the first and second control signal inhibiting means, respectively.
A receiving device for a band compressed image signal, characterized in that the second control signal inhibiting means and the first controlling means are configured to work together.