JPH04207353A - Image prediction encoding device - Google Patents

Abstract

PURPOSE:To facilitate writing and reading out control for obtaining previous frame image signals by reading the reverse quantized differences alternately out of each of two previous frame memories while writing the reverse quantized differences into these previous frame memories. CONSTITUTION:The two previous frame memories 8, 9 are provided. While the reverse quantized difference is written into the one previous frame memory 8, the difference in the previous frame is read as the previous frame image signal out of the other memory 9. The writing/reading out modes of the previous frame memories 8, 9 are alternately reversed at every frame changeover 7 if while the reverse quantized differences in the present frame 1 are written alternately into the respective previous frame memories 8, 9 provided in two faces at every frame changeover 7 in such a manner, the reverse quantized differences in the previous frames 8, 9 are read as the previous frame image signals out of the respective previous frame memories 8, 9. The writing and reading out control for the previous frame memories for obtaining the previous frame image signals is facilitated in this way.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to an image predictive encoding device for encoding and compressing an image signal using a predictive encoding method, and particularly relates to an image predictive encoding device for encoding and compressing an image signal using a predictive encoding method. The present invention relates to an image predictive encoding device in which writing and successive output control to the previous frame memory is facilitated by providing two frame memories as the frame memory.

[Prior art] For example, 1 when encoding and compressing a TV image signal with high efficiency.
As a method, an interframe predictive coding method is widely used, and when this method is used, a previous frame memory is required to obtain a previous frame image signal.

Incidentally, as a device related to this type of technology, for example, the one described in Japanese Patent Publication No. Jl-15231 (↓) is known. In this case, the previous frame memory has a one-sided configuration, and the difference between the previous frame image signal from the previous frame memory and the current frame-to-frame image signal is determined through a delay circuit, and then non-linearly quantized. After that, it is encoded and compressed.

U Problems to be Solved by the Invention] However, if only one side of the previous frame memory is provided, writing to the previous frame memory is repeated within one frame. Complexity is inevitable.

SUMMARY OF THE INVENTION An object of the present invention is to provide an image predictive encoding device that facilitates writing and continuous output control to a previous frame memory for obtaining a previous frame image signal.

[Means for solving the problem] The above purpose is to provide two previous frame memories in the predictive coding loop, and each time a frame is switched, the dequantized difference is stored alternately in each of these previous frame memories. This is achieved by arranging that the dequantized difference is read out alternately from each of these memories as a previous frame image signal in one write operation.

[Operation] Generally, in the interframe predictive coding method, the difference between the current frame image signal and the predicted signal is linearly quantized and then encoded and compressed. After the difference was dequantized, it was obtained as a previous frame image signal via the previous frame memory]-1 A prediction signal is generated by multiplying this by a prediction coefficient.
The previous frame memory is provided on two sides in order to facilitate writing/successive control to the previous frame memory. As a result, in one frame, while the dequantized difference is written in the previous frame memory, in the other frame, the difference in the previous frame is read out as the previous frame image signal, and the next frame is read out as the previous frame image signal. In a frame, while the difference in the previous frame is read out as a previous frame image signal from one frame memory, the dequantized difference in the current frame can be written in the other frame memory.

In this way, each time a frame is switched, the inverse of the current frame is alternately written to each of the two previously installed previous frame memories as a child difference, while the data from each of those previous frame memories is alternately written. If the dequantized difference in the previous frame is configured to be read out as the previous frame image signal alternately, the write/read modes in each previous frame memory are switched to be opposite to each other each time the frame is switched. However, since it is fixed to one of the modes within the frame, the writing and
This facilitates continuous control.

[Example] Hereinafter, the present invention will be explained with reference to the accompanying drawings.

The figure shows a schematic configuration of an image predictive encoding device according to the present invention. In this case, the comparator 2 calculates the difference between the multivalued digitized current frame image signal from the current frame memory 1 and the prediction signal in units of blocks (for example, 8 x 8 pixels). The difference is nonlinearly quantized by a quantizer 3. The non-linearly quantized difference is encoded and compressed by variable improvement such as a Huffman code in the encoder 10, and then transmitted to the opposing device as an encoded compressed output or stored in the memory 2. This is what has become.

Now, in order to obtain the prediction signal required for interframe predictive coding, the nonlinearly quantized difference from the quantizer 3 is dequantized by the dequantizer 4. The predicted signal to be sent to the comparator 2 is added to the dequantized difference by the adder 5. By adding this predicted signal, the difference from comparator 2 is quantized by quantizer 3 while taking into account the integral value of quantization noise generated by quantizer 3, so the accumulation of quantization noise is This can be prevented. The difference to which the predicted signal is added from the adder 5 is once delayed stored in the frame memory so as to be obtained as the previous frame image signal, but in the case of the present invention, the difference from the adder 5 is stored every time a frame is switched. The differences are alternately written to the previous frame memory 8.9 via the previous frame memory switching section 7. That is, the front part L,
- In each of the frame memories 8 and 9, the write/read modes are switched to be opposite to each other each time frames are switched. As a result, compared to a one-sided frame memory, writing and continuous output can be performed more easily. Each time a frame is switched, the previous frame image signal which is read out alternately from the previous frame memory 8.9 is multiplied by a preset prediction coefficient in the prediction coefficient multiplier 6, thereby transmitting the prediction to the comparator 2. The signal is obtained.

"Effects of the Invention" As explained above, according to the present invention, writing and writing to the previous frame memory to obtain the previous frame image signal is possible.
An image predictive coding device that facilitates successive control can be obtained.

[Brief explanation of the drawing]

The figure is a diagram showing a schematic configuration of an image predictive encoding device according to the present invention. 1... Current frame memory 2... Comparator 3... Quantizer 4... Inverse quantizer 5... Adder 6... T measurement coefficient multiplier 7... Previous frame switching Part 8.9...Previous frame memory 10...Encoder patent applicant Hitachi Communication Systems Co., Ltd. Agent Patent attorney Masami Akimoto

Claims (1)

[Claims] 1. The difference between the current frame image signal and the prediction signal based on the previous frame image signal generated in the predictive coding loop is nonlinearly quantized and encoded and compressed. After inverse quantization, the quantized difference is obtained as a previous frame image signal via the previous frame memory, and
An image predictive encoding device configured to generate a predictive signal by multiplying the image signal by a prediction coefficient, the image predictive encoding device comprising: a frame memory provided in a two-sided predictive encoding loop as a previous frame memory; The image prediction method is configured such that each time a frame is switched, inverse quantized differences are written alternately as the previous frame image signal, while the previous frame image signal is read out alternately from each of the memories. Encoding device.