IoT provides a platform for every device to be connected by means of a stable internet connection. The interoperability of the devices helps to communicate and exchange data between one another and increases the power consumption of devices. When creating a new IoT system or rebuilding the existing ones, the low power circuit design is considered as an essential factor. In the low power circuit design, the most challenging aspect to overcome is to reduce the leakage power, because the battery-operated devices are fast in draining energy when left long in the standby mode. Reducing the delay of a ripple carry adder can be only accomplished with Carry-Skip Adder (CSA) with minimal effort when compared to other techniques like a carry-look ahead adder. The carry skip adder belongs to the family of bypass adders, and its main aim is to improve the worst-case delay of the IoT device based on its area and power consumption. The CSA used in the proposed method for the IoT processor helps to increase the performance of the system relative to average power dissipation, leakage power, power delay product, and propagation delay.

物联网为通过稳定的互联网连接来连接每台设备提供了一个平台。设备之间的互操作性有助于彼此之间进行通信和交换数据，并增加了设备的功耗。在创建新的物联网系统或重建现有的物联网系统时，低功耗电路设计被视为必不可少的因素。在低功率电路设计中，要克服的最具挑战性的方面是减少泄漏功率，因为​​当电池处于待机状态时，电池供电的设备消耗能量的速度很快。与其他技术（例如，超前进位加法器）相比，仅使用最小的进位加法器（Carry-Skip Adder，CSA）即可减少纹波进位加法器的延迟。进位跳过加法器属于旁路加法器家族，其主要目的是根据面积和功耗来改善IoT设备的最坏情况延迟。相对于平均功耗，泄漏功率，功率延迟乘积和传播延迟，所提出的用于IoT处理器的方法中使用的CSA有助于提高系统性能。