عرض تفاصيل البحث

ادناه جميع التفاصيل الخاصة بالبحث المطلوب عرضه. توفر هذه المنصة معلومات اساسية حول البحث, لمزيد من التفاصيل يرجى متابعة التصفح من خلال الضغط على الرابط الاصلي للبحث او رابط DOI.

عنوان البحث
A Lightweight Huffman-Based Differential Encoding Lossless Compression Technique In Iot For Smart Agriculture
عنوان المجلة
International Journal Of Computing And Digital Systems
ISSN-2210-142X
تفاصيل النشر
سنة النشر - 2022 / الفهرس الاصلي للمجلة - 11 : 1 (عدد الصفحات 11)
تصنيف البحث
Computer Science - المجموعة العلمية
البحث والاستدامة
الهدف 9– الصناعة والابتكار والبنية التحتية   المزيد حول هذا الهدف
البحث والمجتمع
نعم , يدعم

اسم الباحثجهة الانتساببلد الباحث
علي كاظم محمد الغرابي جامعة بابل العراق

Major advantages occur in modern agriculture, including effective position and space needs, sufficient meteorological management, water efficiency, and controlled nutrient use. The Internet of Things (IoT) definition suggests that different ”things,” such as communication devices as well as all other physical objects in the world, can be connected and regulated over the Internet. Wireless Sensor Networks (WSNs), in particular, may be thought of as important data collection and transmission systems. It is possible to build automated systems for improved agricultural environmental control using the IoT and WSN. But WSN is suffering from the motes’ limited energy supplies, which decreases the total network’s lifetime. Each mote periodically collects the tracked feature and transmits the data to the sink for additional study. This method of transmitting massive volumes of data allows the sensor node to use high energy and substantial bandwidth on the network. In this article, we suggest a lightweight lossless compression algorithm based on Differential Encoding (DE) and Huffman techniques that is particularly beneficial for IoT sensor nodes that monitor the features of the environment, especially those with limited computing and memory resources. Instead of trying to formulate innovative ad hoc algorithms, we demonstrate that, provided general awareness of the features to be monitored, classical Huffman coding can be used effectively to describe the same features that are measured at various time periods and locations. Results utilizing temperature measurements indicate that it outperforms common methods developed especially for WSNs, even though the suggested system does not reach the theoretical maximum.