Patent Document

CROSS-REFERENCE TO RELATED APPLICATIONS 
   The entire disclosures of Japanese Patent Application Nos. 2004-127146 and 2004-322296 including their specifications, claims, drawings, and abstracts are incorporated herein by reference. 
   BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to an encoding control circuit for controlling the number of generated codes in an image encoding circuit, and to an encoding circuit using the encoding control circuit. 
   2. Description of the Prior Art 
   Electronic devices very commonly employ a processing which converts analog image signals into digital signals by sampling the image signals and quantizing the sampling values. Moreover, the encoding processing such as compression processing for orthogonally transforming the sampling values is also performed. For example, the Hadamard transform corresponds to the above encoding processing. 
   Control of the number of generated codes is realized by applying division to each orthogonally-transformed component. The component of n-degree orthogonal transformation is shown as H=S(n) (n is 0 to n−1). 
   Encoding control is realized by diving a component H by a value Q (quantization step). For example, when H is a value shown by 10 bits, H can be shown by 7 bits when dividing H by Q=8 and it is possible to decrease the number of generated codes by a value equivalent to 7 bits. 
   However, when increasing the value of Q in this encoding control, it is impossible to restore an image to an original image after reverse orthogonal transformation because the quantization step becomes large and the quantity of information is reduced as a result of encoding. For example, in the case of MPEG encoding, the image quality may be greatly deteriorated due to block noise. 
   SUMMARY OF THE INVENTION 
   The present invention solves the above-described problem by providing an encoding control circuit for controlling the number of codes generated in an image encoding circuit, which selects and outputs any of a first image signal not deteriorating a frequency bandwidth and a second image signal deteriorating the frequency bandwidth in accordance with an accumulated value for the number of codes in the image encoding circuit. 
   Moreover, an encoding control circuit of the present invention may be an encoding control circuit for controlling the number of codes generated in an image encoding circuit, comprising: a comparison-determination circuit for comparing an accumulated value of an actual number of codes of a constant time interval in an encoding unit period in the image encoding circuit with a preset reference number of codes corresponding to the time interval; a switch for selecting any of a first image signal not deteriorating a frequency bandwidth and a second image signal deteriorating the frequency bandwidth and inputting it to the image encoding circuit; and switch control means for making the switch select the first image signal when the accumulated value codes does not exceed the reference number and causing the switch to select the second image signal when the accumulated value exceeds the reference number. 
   Moreover, the present invention also provides an encoding circuit for encoding and outputting an image signal, comprising: an information-quantity decreasing portion for generating a second image signal by decreasing the information quantity of a first image signal and outputting the second image signal; a selecting portion for selecting any of the first image signal and the second image signal in accordance with a selection signal; an encoder for encoding the image signal output from the selecting circuit; a number-of-generated-codes accumulating and calculating portion for accumulating the number of codes of encoded image signals output from the encoder in a predetermined encoding unit period; and a comparator for comparing the actual values with a reference value predetermined for each the time interval and outputting the selection signal. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a block diagram showing an encoding circuit of an embodiment of the present invention; 
       FIG. 2  illustrates an example relationship between the accumulated value of actual number of generated codes at constant time intervals and the accumulated value of a reference number of generated codes preset corresponding to the time intervals; and 
       FIG. 3  is a block diagram showing an example encoder. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIG. 1  is a block diagram showing an encoding circuit  1 . An input image signal is a digitized image signal (luminance/color-difference signal or RGB signal). An image signal passing through a low-pass filter (LPF)  10 , which is a digital filter, and a sampling-rate decreasing portion  11  is input to the first input terminal of a switch  12  and an image signal is directly input to the second input terminal of the switch  12 . The switch  12  selects an image signal in accordance with a comparison result by a comparator  16  to be described later. The low-pass filter  10  passes only the low frequency band of an input signal. For example, in the present embodiment, the frequency band of an image signal is narrowed to half. Moreover, the sampling-rate decreasing portion  11  outputs only every other value output from the low-pass filter  10 . That is, the portion  11  discards every other output value, thereby for decreasing the sampling rate by one half. 
   An image signal selected by the switch  12  is input to the encoder  13 . The encoding method employed by the encoder  13  is not restricted by the present invention. Known encoding methods include orthogonal transforming methods such as DCT (discrete cosine transformation) and Hadamard transformation. In the present example, the encoder  13  is described by assuming that the encoder  13  performs the Hadamard transformation. The encoder  13  for performing the Hadamard transformation is shown in  FIG. 3  as an example. 
   An image signal delayed by a frame delay memory  13   a  is input to a first Hadamard transformation circuit  13   b  of the encoder  13 . Moreover, an image signal is directly input to a second Hadamard transformation circuit  13   c . The Hadamard transformation circuits  13   b  and  13   c  respectively apply two-dimensional Hadamard transformation to the image signals and output the signals to an adder  13   d  and a subtracter  13   e . The number of components of the two-dimensional Hadamard transformation becomes m×n in the case of a block of rows (m) and columns (n). For example, in the case of m=2 and n=2, four components are output. 
   The adder  13   d  and subtracter  13   e  add and subtract components of the two-dimensional Hadamard transformation from the first Hadamard transformation circuit  13   b  and the second Hadamard transformation circuit  13   c . In this case, when the components for a signal having no frame delay are S(0) to S(m×n−1) and components for a signal having a frame delay are FS(0) to FS(m×n−1), the adder  13   d  and subtracter  13   e  at the next stage execute the following operations:
 
Adder= S ( k )+ FS ( k )
 
Subtracter= S ( k )− FS ( k )
 
   Quantizing portions  13   f  and  13   g  respectively apply quantization processing to each computation result. Both quantization results are connected in one-dimensional arrangement and input to a Huffman encoding circuit  13   h . The Huffman encoder  13   h  performs widely-known Huffman encoding. For example, a not-illustrated transmitting portion is set to the rear stage of the Huffman encoder  13   h . When the encoder  13  is set to, for example, a TV receiver, a received program can be transmitted from the transmitting portion. A child TV set which is an accessory of the TV receiver displays an image by receiving a transmission signal from the transmitting portion, performing demodulation processing, and moreover performing decoding processing. 
   In the case of the encoder  13 , the encoding unit period is set to a two-frame period (four-field period) of an image signal. Moreover, delay time is set to a two-field period by a frame delay memory. Specifically, in the case of a frame-delayed signal and a signal having no frame delay, a first field corresponds to a third field. Hadamard transformation is applied to blocks to which the both fields correspond and the above addition and subtraction are performed. Similarly, a second field corresponds to a fourth field. Hadamard transformation is applied to blocks to which the both fields correspond and the above addition and subtraction are performed. Moreover, in the next encoding unit period, a fifth field corresponds to a seventh field and a sixth field corresponds to an eighth field. 
   A number-of-generated-codes accumulating and calculating portion  14  accumulates the number of codes output from the encoder  13  by a predetermined period and outputs it. The accumulated value (hereafter referred to as actual value) of actual number of generated codes at constant time intervals in the encoding unit period output from the encoder  13  is calculated. That is, the number of codes output from the encoder  13  is accumulated for the encoding unit period and the value is output as an actual value for every constant time interval. 
   A reference value generating portion  15  outputs a reference number of generated codes (hereafter referred to as reference value) preset synchronously with a time interval in which an actual value is output. For example, the reference value generating portion  15  is constituted of, for example, a memory and sequentially outputs holding data (R 1 , R 2 , R 3 , . . . , Rn) by inputting a counted value (time) from a not-illustrated counter as an address. 
   A comparator  16  receives an actual value from the number-of-generated-codes accumulating and calculating portion  14  and a reference value from the reference value generating portion  15 , compares the actual value with the reference value, and outputs the results of the comparison. Specifically, when the actual value is smaller than the reference value, the comparator  16  outputs Low ( 0 ) to the switch  12  and High ( 1 ) to the switch  12  when the actual value is larger than the reference value. 
   When receiving Low ( 0 ), the switch  12  directly encodes an input image signal and supplies it to the encoder  13  but when receiving High ( 1 ), the switch  12  supplies an input image signal passing through the low-pass filter  10  to the encoder  13 . 
     FIG. 2  is an illustration showing elapsed time versus accumulated generated codes. R 1 , R 2 , R 3 , . . . , Rn in  FIG. 2  show reference values output from the reference value generating portion  15  for every certain time. In the example of this embodiment, the reference value is value on a straight line shown by a linear expression to time. However, it is also possible to set the reference value as a value on a curve. In this case, when an encoding unit period is a period from time  0  to time n, a reference value supplied to the comparator  16  becomes R 0  at the time  0 , R 1  at the time  1 , and Rn at the time n. 
   Moreover, a thick line in  FIG. 2  shows the accumulated value (actual value) of number of generated codes when number-of-codes control is not performed. The comparator  16  outputs Low ( 0 ) while the actual value is smaller than the reference value. Therefore, the switch  12  directly supplies an input image signal to the encoder  13 . At the position shown by the point P in  FIG. 2 , it is assumed that the actual value exceeds the reference value. In this case, an output of the comparator  16  is set to High ( 1 ) and an input image signal passing through the low-pass filter  10  and sampling rate decreasing portion  11  is input to the encoder  13  by the switch  12 . Because the input image signal passing through the low-pass filter  10  and sampling rate decreasing portion  11  is a signal from which a frequency band and sampling rate are removed, the number of generated codes in the encoder  13  thereafter is decreased to show the change shown by the thick dotted line in  FIG. 2 . 
   When considering a case in which the frequency band of an input image signal is restricted to one half, and the sampling rate of the signal is decreased to one half by the low-pass filter  10 , the number of codes generated in the encoder  13  is halved. In this ease, when the number of codes generated is not adjusted and it is assumed that an actual value (accumulated number of codes) on the extension line of a straight line connecting the point Q with the original in  FIG. 2  is increased. When adjustment of the number of codes generated is staffed at time X Q , the number of codes is halved due to the decrease of the frequency band and decrease of the sampling rate. In other words, the increase rate of the actual value (accumulated number of codes) is halved. A condition for an actual value to which encoding control is applied not to exceed Rn in an encoding period (from time  0  to time n) can be expressed as follows. When the coordinates of the point Q are (X Q , Y Q ), the following expression (1) can be obtained.
 
( Y   Q /2 X   Q )× n +( Y   Q /2)&lt; Rn   (1)
 
Y Q  is obtained by the following expression (2).
 
 Y   Q &lt;2 ×X   Q   ×Rn /( n+X   Q )  (2)
 
In this case, X Q =0, 1, 2, . . . , n.
 
   That is, by obtaining reference values of R 0  to Rn in accordance with the value Y Q  shown by the expression (2), the accumulated number of codes does not exceed Rn. Moreover, the condition is an assumption that the subsequent number of codes increases at the same gradient at the point Q. The same condition can be obtained even when the number of codes increases at two times gradient. The conditional expression in such a case becomes
 
( Y   Q   /X   Q )× n +( Y   Q /2)&lt; Rn.  
 
   The data rate of an output of the encoder  13  in the above encoding control can be shown by Rn/n (bps). The transmission band of a transmission route is set in accordance with the data rate to transmit an encoding signal to the transmission route. Or, when a transmission band is specified, other reference value is set by setting the reference value Rn in accordance with the transmission band. 
   While an input image signal from the low-pass filter  10  is selected, the resolution of the image signal may be halved. For example, when the encoding unit period of the encoder  13  is equal to a two-frame period of an image signal, periods in which input image signals passing through the low-pass filter  10  are selected are stochastically concentrated in the latter half of an encoding period. Therefore, there is an advantage that the periods are not recognized as image quality deterioration. As an extreme example, in a two-frame (four-field) period, when the period in which an input image signal passing through the low-pass filter  10  is selected is the final fourth field, three images at a high resolution are displayed, and thereafter only one image at a low resolution is presented. Therefore, there is little recognizable deterioration in image quality. 
   In the case of the above example, the switch  12  is operated based on comparison between the accumulated value and reference value of the actual number of generated codes. However, it is also possible to operate the switch  12  when a change of the number of codes (increase gradient) is detected or when the detected change exceeds a predetermined value.

Technology Category: h