This paper proposes a low power optimization framework based on retargetable compiler, which aims at the shortcomings of traditional low power optimization in generalization.
文章针对传统功耗优化缺乏通用性的缺点,提出一个基于可重定向编译器的功耗优化框架。
Combining with features of ASIP architecture, study on application specific low power optimization technology focusing on instruction set (program code), pipeline and storage.
结合ASIP体系结构特征,以应用特征为指导,针对指令集(程序代码)、流水线和存储部件进行了低功耗优化研究。
It's focused on low power consumption, providing wireless support out of the box and small screen optimization.
它因低功耗而备受关注,并且提供无线支持以及针对小屏幕进行优化。
As the theoretic foundation of low power, power optimization from design levels of digital circuit has been discussed with emphasis based on the basic power consumption equation.
作为低功耗设计的理论基础,本文从数字电路的基本功耗方程出发,重点讨论了各设计层次优化功耗的方法;
The design for low power, including its background, principle and techniques, is systematically described, with emphasis on system-level power optimization technologies targeted for SOC's.
文章全面系统地介绍了低功耗设计的相关内容,包括背景、原理和不同层次的功耗优化技术,着重介绍了面向SOC的系统级功耗优化技术。
And adopting the optimization design, high conductivity, the electromagnetic material production equipment in no-load loss low power output, more powerful, and stability, long service life.
并采用优化设计、高导电磁材料制作,致使设备在空载时损耗低、功率输出更强劲、稳定、寿命更长。
This dissertation detailedly investigate the symbolic logic and some typical techniques for low power FSM logic synthesis and optimization.
论文详细讨论了低功耗有限状态机综合与优化中的符号逻辑和一些典型方法。
In this thesis, we introduce some basic knowledge of high-level synthesis, and research feather the high-level optimization techniques for low power.
本文综述了高层次综合的相关理论,并对高层次综合阶段的功耗优化技术进行了研究。
So it is important to do some research on the Synthesis and Optimization of Low Power FSM.
因此对低功耗有限状态机的综合与优化的研究有着重要意义。
Then, we propose a low-power optimization algorithm based on WCET analysis.
然后,提出了一种基于WCET分析的低功耗优化算法。
Parameter optimization of power system stabilizers is very important to restrain the low-frequency oscillation of multi-machine systems.
电力系统稳定器参数的优化对于抑制多机电力系统低频振荡具有非常重要的意义。
Thus, it makes low-power optimization a kernel faced in RFID transponder design.
这样,低功耗优化就成为无源射频识别标签设计中的一个核心问题。
Thus, it makes low-power optimization a kernel faced in RFID transponder design.
这样,低功耗优化就成为无源射频识别标签设计中的一个核心问题。
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