Abstract:
Some representative embodiments are directed to systems and methods for compressing a data set. In one embodiment, a method comprises receiving a frame of data to be encoded, generating a residual frame that represents a difference between the received frame and one or several reference frames, performing a respective sum of absolute differences (SAD) calculation for each block within the residual frame, and applying a transform function to each data value within the residual frame, wherein the transform function is at least a function of a SAD value calculated for the block containing the respective data value.

Description:
TECHNICAL FIELD 
   The present invention is generally directed to systems and methods for compressing data. 
   BACKGROUND 
   Multimedia data (video, audio, text, and combinations thereof) used by many applications presents a large degree of complexity. In many applications, such complexity is primarily addressed through data compression to achieve efficient processing, delivery, presentation, and other important functions involving the multimedia data. 
   Data compression algorithms rely upon the redundancy in a data set to obtain coding efficiency. In general, a priori knowledge of the characteristics of data sets are used to select coding algorithms for the data sets to achieve data compression. For example, image compression algorithms rely upon spatial correlation in image data. Specifically, it is known that the level of a respective pixel is closely related to the level of adjacent pixels. Likewise, a level of a pixel in a respective video frame is closely related to the level of the same pixel and/or adjacent pixels in a prior video frame. Accordingly, many image and video compression algorithms generate “residual” or “difference” signals that are encoded using run lengths and other techniques to take advantage of the spatial and/or temporal correlation. For example, the compression algorithms defined by the Motion Picture Expert&#39;s Group (MPEG) standards use these techniques. 
   The performance of a compression algorithm is dependent upon the choice of the reference mechanism or functionality used to generate the residual signal. In video compression algorithms, the selection of the reference frame occurs by assuming that a relatively restrictive temporal relationship exists. Following this assumption, the reference frame is typically selected by examining a limited number of previous frames from a frame being encoded. If the video data exhibits a relatively tight temporal correlation, compression performance is acceptable. However, multimedia data does not necessarily always follow such assumptions. Accordingly, known compression algorithms may not be able to effectively exploit the redundancy that exists in many multimedia data sets. 
   SUMMARY 
   Some representative embodiments are generally related to algorithms that compress a current data frame by calculating and encoding residual data using one or several reference frames of data. Furthermore, some representative embodiments enable a greater amount of compression to occur by generating optimal residual data. In some representative embodiments, the optimal residual data is a function of many factors, such as the current frame, one or several reference frames, sum of absolute differences (SAD) values, motion vector values, block energy, and/or other system variables. For example, a value in a traditional residual data block may be transformed or scaled by a function of a SAD value associated with that block. The transformed value is then used to encode the residual value for the particular data element. The transform function is preferably selected to differentiate between information that can be discarded (e.g., noise, artifacts, and/or the like) and information that is important to the perceived “quality” of data. By enabling such differentiation to occur, some representative embodiments enable a greater amount of data compression to occur. 
   The foregoing has outlined rather broadly the features and technical advantages of the present invention in order that the detailed description of the invention that follows may be better understood. Additional features and advantages of the invention will be described hereinafter which form the subject of the claims of the invention. It should be appreciated that the conception and specific embodiment disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. It should also be realized that such equivalent constructions do not depart from the invention as set forth in the appended claims. The novel features which are believed to be characteristic of the invention, both as to its organization and method of operation, together with further objects and advantages will be better understood from the following description when considered in connection with the accompanying figures. It is to be expressly understood, however, that each of the figures is provided for the purpose of illustration and description only and is not intended as a definition of the limits of the present invention. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     For a more complete understanding of the present invention, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which: 
       FIG. 1  depicts a flowchart for compressing a video frame according to one representative embodiment. 
       FIGS. 2-4  depict transform functions of SAD values used to scale residual values according to some representative embodiments. 
       FIG. 5  depicts a system that performs data compression according to one representative embodiment. 
   

   DETAILED DESCRIPTION 
   To illustrate compression of a video frame according to one representative embodiment, reference is made to  FIG. 1 . The process flow of  FIG. 1  begins at step  101 . In step  101 , a set of non-overlapping macroblocks of pixels are defined. The macroblocks may be subdivided into subblocks of size 16×16, 16×8, 8×16, 8×8, 4×8, 4×4, and/or the like in the manner disclosed by multiple block-size motion estimation. The different patterns of subdivision may be applied to respective macroblocks. Also, the subdivision may vary on a frame by frame basis. Each macroblock may include more than one component or channel (e.g., RGB, YIQ, YUV, YCbCr, etc). 
   In step  102 , for each block within the current frame, a best-matching block is obtained. Each best-matching block may be identified from a block of the same size in a reference frame. Alternatively, the best-matching block may originate from a larger block in a manner similar to overlapping motion estimation. Moreover, each best-matching block may be identified from a weighted linear combination of adjacent blocks in a manner similar to sub-pixel motion estimation or overlapping motion estimation/compensation algorithms. The weights applied to the multiple blocks to generate a best-matching block may vary on a pixel by pixel basis. Also, the best-matching block may be identified from a combination of previous frames within a predefined distance and subsequent frames with a predefined distance. In one embodiment, the search for best-matching blocks for the blocks within frame i may traverse frames i−2, i−1, i+1, i+2 and any blocks therein. The identification of the best-matching block may also use the current frame. Furthermore, a respective best-matching block may be formed using a repetition of selected pixels in a manner similar to extended motion estimation. As an example, steps  101  and  102  may be performed using standard video processing algorithms such as the algorithms defined in the various MPEG compression standards. 
   In step  103 , for each block in the current frame, an analysis of its corresponding best matching block is performed. The analysis may involve calculation of a conventional residual frame. The analysis may also include performing a respective sum of absolute differences calculation for each residual block, determining the energy in each residual block, analyzing the motion vector associated with each residual block, examining the past frame history of such characteristics, and/or the like. 
   In step  104 , an optimal residual frame is calculated as a function of one or several variables (e.g., optimal_residual=function_F(conventional_residual, one or several other parameters). In one embodiment, a transform function of the selected parameter(s) associated with each block of the conventional residual frame is employed. The transform function is evaluated for each data element in the conventional residual frame and each data element in the residual frame is scaled by the resulting value. After each data element has been scaled, the conventional residual frame has been converted into the optimal residual frame. Multiple functions may also be employed to generate a single optimal residual frame. The functions may be linear or non-linear. 
   Each function is selected to differentiate between signal information that is useful to the perceived quality of the data and signal information that is not important (such as errors, noise, artifacts, and/or the like). Also, the functions may take many forms and/or formats. For example, suppose the compression algorithm is applied to video taken according to a slow motion “drag” of the camera. A low complexity function can be applied. Alternatively, when a scene possesses more complex camera movements and object movements, a more complex function can be used to decide what information in the residual can be discarded (or equivalently what is the best residual frame that can be produced given computational, resource, and time constraints). The optimal reference frame differs from known residual frames in that the optimal reference frame does not encode all differences. Specifically, the application of the transform function(s) removes information that is not important to the perceived quality of the data. Accordingly, a greater amount of compression can be achieved. 
   In step  105 , typical residual processing may occur such as application of the discrete cosine transform (DCT) or other transforms, quantization, entropy encoding (e.g., Huffman encoding, arithmetic encoding, etc.), association of motion vectors, and/or the like. The typical processing defined by the MPEG standards may be employed. 
   After compression, the data can be recovered using traditional processing. For example, conventional MPEG decoders may be used to recover the compressed data. Due to the application of the transform function(s), the exact video data of a particular frame might not be recovered (i.e., the compression is lossy). However, the transform functions are preferably selected such that erroneous or otherwise less important information is omitted from the residual data. Accordingly, the viewer of the decompressed video data does not experience an undue reduction in the image quality. 
   Although  FIG. 1  describes compression of video data, the present invention is not so limited. Some representative embodiments may be employed upon any type of data that is amenable to lossy compression. 
     FIG. 2  depicts function  200  that may be applied to residual data according to one representative embodiment. Function  200  is a piece-wise linear function of the SAD value. Function  200  is divided into several regions with each region having its own parameter value (in the simplified linear case, the slope of the line). For small SAD values, the line can be steep so that the optimal residual data is reduced (to reflect the fact that the difference may be noise or an error). Alternatively, for larger SAD values, the line becomes flat so that the full residual value can be encoded. The regions can be obtained via training or previous statistics. 
     FIGS. 3 and 4  depict functions  300  and  400  respectively according to other representative embodiments. Function  300  suppresses differences associated with small SAD values while emphasizing differences associated with larger SAD values (e.g., “important” new video features). Function  400  possesses a “bandpass” shape. Differences associated with small and large SAD values are suppressed. Function  400  may be applied when prior knowledge indicates that large difference values may be unreliable and, hence, should be suppressed. In other embodiments, the transform functions may similarly be functions of energy, entropy, and/or motion vectors. 
     FIG. 5  depicts system  500  that compresses video data according to one representative embodiment. System  500  may be implemented using a computer platform that includes suitable computing resources such as processor  501 , display  502 , and non-volatile memory  503 . Non-volatile memory  503  may be used to store code or software instructions that perform the compression of video data  504 . For example, a current video frame may be processed by best-matching block module  505 . After the identification of best matching blocks for a current frame of data from one or several reference frames, conventional residual calculation module  506  generates a residual frame. Transform function(s) module  507  uses one or several variables to scale the data values of the conventional residual frame to generate an optimal residual frame. The variables may include SAD values, energy values, motion vector values, and/or the like. Transform function module(s)  507  removes information from the residual frame that is not important to image quality or that may represent noise or errors. The optimal residual frame is processed by MPEG encoding module  508  to generate compressed video data  509 . Compressed video data  509  can be accessed using conventional MPEG decoder/viewer module  510 . 
   Although MPEG encoding has been discussed for some representative embodiments, any suitable encoding scheme may be employed according to other representative embodiments. Additionally, although some representative embodiments may been described in terms of software, other suitable logic elements could be employed such as integrated circuitry. 
   Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the invention as defined by the appended claims. Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification. As one will readily appreciate from the disclosure, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps.