Abstract: The ‘Radio Frequency Identifcation (RFID)’ and Wireless-Sensor Networks, (WSNs) (Ivana, 2017) which are one among the main technologies while characterization of ‘Internet of Things (IoT)’ that shape an ‘Integrated Network’ well-known as RFID-Sensor Networks (RSNs) (Al-Fagih, 2013). These networks represent an assorted platform enabling lot many applications in the context of IoT. The outcomes of this particular aspect are additional to ‘functional’, ‘scalable’, and ‘cost-effective’, when this assorted platform is explored. The main drawback of most ‘Integrated RSN architectures’ existing in literature, in typical, functionally leaning and fail to realize challenges presented by ‘Ultra-large-scale deployments’ in requisites of economic, interoperability and connectivity. In the current wireless topologies with ordinary integration called ‘Courier Nodes (CNs)’ are not successful in effcient utilization of ever-present components. Some of the examples of CNs comprise handheld-devices, smart phone, on-board transceiver automobiles, and public-transit systems with full or partially deterministic mobility traces. CNs is important in facilitating the whole host of IoT functionalities. In this work, an argument has been done that an (Al-Fagih, 2013) IoT setting is always characterized by i) The ability to identify ii) Seamless integration iii) Ubiquitous connectivity and iv) Delay-tolerance. Keywords: Internet of Things (IoT), Light nodes, Networking, RFID, Wireless-Sensor Networks (WSNs). I. IntroductIon The Internet of Things (IoT) describes a worldwide network of intercommunicating devices which integrates the ubiquitous communications, persistent computing and ambient intelligence. At this instant (IoT) should be seen as vision where things such as home appliances, smart materials etc., are readable, identifable, locatable, addressable and/or controllable through the Internet. It will give the source of several novel applications like energy monitoring, transport safety systems, building security etc. This idea will defnitely change with time, mostly as synergies between ‘Identifcation Technologies’, Wireless- IoT with Integrated Architecture M. Veeranjaneyulu 1 , D. V. Ramakoti Reddy 2 , P. Seetharamaiah 3* 1 Dept. of Instrumentation Engineering, Andhra University, Visakhapatnam, Andhra Pradesh, India. Email: veeramaddali@gmail.com 2 Dept. of Instrumentation Engineering, Andhra University, Visakhapatnam, Andhra Pradesh, India. Email: kreddy_67@yahoo.co.in 3 Dept. of Computer Science and Systems Engineering, Andhra University, Visakhapatnam, Andhra Pradesh, India. Email: psrama@gmail.com *Corresponding Author International Journal of System and Software Engineering Volume 5 Issue 2, December 2017 ISSN.: 2321-6107 Sensor Networks, ‘Intelligent Devices’ and Nanotechnology will facilitate a number of advanced applications. The central element of IoT, is to structure ‘large-scale’, ‘heterogeneous’, ‘distributed network’ through an integrated architecture with the use of abundant standards related to communication, by combining / integrating them. In this view, the ‘Radio Frequency Identifcation (RFID) systems and Wireless-Sensor Networks (WSNs)’ signifes to be often leading and assuring technologies (Brock, 2001; E. Welbourne, 2009; Swan, 2012; D. Christin, 2009). The wireless-sensor network, technologically fulfll the requirements for ‘Transmission Control Protocol (TCP/IP)’, including requirements for web- services, and GPRS techniques (Apurva, 2016). It has an advantage of low cost, low power. The system comprises of wireless-sensor network-nodes and network-management podium (Apurva, 2016). Further WSN plays an important role in poly house agriculture which continuously monitors various environmental and soil parameters for sustainable plant growth (Chavan, 2015). The countries with less rain fall uses the recent net house technology in agricultural felds for yielding outstanding product and help to manage the growing demand of the people. In spite of all adverse environmental conditions the production increases signifcantly. The parameters such as temperature, humidity and luminous intensity required to be maintaining under control. Parameter Monitoring (WSN-EPM) is very expensive. However, in recent technologies including WSN based Environment. Therefore, the objective is to develop ‘low cost’ and ‘low power’ WSN-EPM (Agarkar, 2010). There has been an enormous development in technological improvements in the feld of agricultural parameters like light, moisture, temperature and humidity, for the sake of farm feld yield (Apurva, 2016) (Ms. Ragini, 2015) (Karande, 2014). The monitoring and control activities are being done by control units. In order to improve crop yield and agriculture production, ‘Wireless Farming Systems’ are used in real-time which issues admonition on the hand-held mobile device regarding issues viz., ‘weather’, ‘hydro level’, ‘wind-speed’, ‘wind-direction’, ‘food warning’, apart from facilitating alerts in case of abnormal situations (Ms. Ragini, 2015).