Low Power的业界专著，主要介绍了power model，power分析，基本的Low power手段，后端的低功耗实现方式以及UPF/CPF的语法。

是lowpowerdesign中最经典的一本教材 但是不得应用于商业目的 不然后果自负

Embedded low-power deep learning with TIDL.pdf

低功耗验证是低功耗设计中最为关键的挑战，《低功耗验证方法学》帮助我们创建了一个可重复使用的低功耗设计的验证环境，极大地提升了业界专家们所积累的最优秀的实践经验。本书可以帮助我们找到低功耗设计中的隐患，并且在设计周期的早期就发现这些问题，而不必等到投片以后，因此大大节省了硅片掩膜的成本和工程调试的时间。

Low-Power Design and Power-Aware Verification(2018英文版)，包含了upf相关概念

UPF2.0 standard, low power IC design, IEEE Standard for Design and Verification of Low Power Integrated Circuits

包含UPF 1801-2013，1801-2018，Synopsys支持的UPF commands

Relevant time durations for modern science range from the femtosecond of very fast electronics to the age of the universe, 15 billion years. This corresponds to a range of about 32 orders of magnitude. Moreover, this variable can be controlled and measured with an accuracy better than 10−14 by modern atomic clocks. However, the accuracy that can be obtained by purely electronic circuits, such as integrated circuits, is only of the order of 10−3. This is because there is no combination of available electronic components (like a RC time constant for example) that is more precise and constant with time and temperature. Now, 10−3 corresponds to an error of about 1.5 minute per day, which is totally unacceptable for timekeeping applications. The same is true for applications to modern telecommunications, which exploits the frequency spectrum up to 300Ghz.

该手册描述了整个Soc芯片的有关低功耗的设计方法，以及如何解决低功耗的问题，提供了关于低功耗技术的完整的知识板块

A Low-Power CoAP for Contiki.pdf A Low-Power CoAP for Contiki.pdf