此外,所述上预测性编码器和下预测性编码器可有利地包括B帧和多重预测运动补偿。
Further, the top and bottom predictive coders can advantageously include B-frames and multiple prediction motion compensation.
文中提出了一种用于帧间编码的新的运动预测方法(MEHSSIM),它建立在基于人眼视觉系统的结构相似性的基础之上。
In this paper, a new motion estimation method based on an improved structure similarity is proposed, that is, HVS-based structure similarity (MEHSSIM) for inter-frame encoding.
为了找出编码蛋白质的基因,注释流程结合了“从头开始的基因预测方法”和“与已知基因相似性比较”这两种方法。
To find unknown protein-coding genes, annotation pipelines use a combination of ab initio gene prediction and similarity to experimentally confirmed genes or proteins.
在CELP编码器中,通常用延迟为抽样间隔整数倍的长项预测器表征浊音语音的准周期性。
The CELP Coder usually USES a long-term predictor that the delay is the integer multiples of sampling interval to exploit the quasi-periodic structure of speech.
根据不同等级像素重要性不同的特性,采用改进的嵌入零树小波编码方法对预测结果进行多阈值量化。
Considering pixels of different levels have different significance, we utilize improved embedded zerotree wavelet (EZW) to get multilevel thresholds quantization.
从理论上分析了帧内变换、预测编码算法,得出其优点,并通过实验验证了帧内变换、帧内预测、帧间预测的混合编码方法优越性。
Many newly technique and algorithms are emphatically analysed. Theoretical analysis educes the advantage of latter method, and experiment result validates the superiority of such coding method.
测试结果表明H . 264编码的复杂性主要体现在帧间预测模块中,要加快H . 264的编码速度,就必须对这个模块进行优化。
Testing results show that the complexity of H. 264 encoding is mainly reflected in the inter prediction module. To speed up H. 264 encoding speed, it is necessary to optimize this module.
通过互联网对测序获得的核苷酸序列进行同源性分析 ,并预测新基因编码蛋白质的结构与功能。
The positive clones were sequenced and the sequence data were analyzed using Nucleotide BLAST software of NCBI and Expert Protein Analysis System of Swiss Institute of Bioinformatics.
通过互联网对测序获得的核苷酸序列进行同源性分析 ,并预测新基因编码蛋白质的结构与功能。
The positive clones were sequenced and the sequence data were analyzed using Nucleotide BLAST software of NCBI and Expert Protein Analysis System of Swiss Institute of Bioinformatics.
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