D.C. Wyld et al. (Eds.): NeCoM/WeST/WiMoN 2011, CCIS 197, pp. 242–251, 2011. © Springer-Verlag Berlin Heidelberg 2011 Congestion Control Protocol for Traffic Control in Multimedia Applications Using WSN Sushama Suryawanshi and S.R. Hiray Computer Department, Sinhgad college of Engg., Pune University, Pune, India sushinpune@rediff.com, swapnajah@yahoo.com Abstract. TCP/IP is reliable, connection oriented protocol for data transmission. It performs very well in wired network but in case of wireless sensor network it is not performing with good throughput. Congestion control is a major problem of TCP/IP performance. A sensor is congested if it receives more traffic than its maximum forwarding rate. The nature of sensor deployment leads to unpredictable patterns of connectivity and varied node density. This causes uneven bandwidth provisioning on the forwarding paths. The data sources are often clustered at sensitive areas under scrutiny. They may take similar paths to the base stations. When data converge toward a base station, congestion may occur at sensors that receive more data than they can forward. Similarly for multimedia applications UDP is unreliable. So Datagram Congestion Control Protocol is suggested for timely, reliable delivery in multimedia applications. It is a general purpose transport protocol for establishment, maintenance and teardown of an unreliable packet flow, and Congestion control of packet. For multimedia applications timely performance of TCP/IP is very important. So Extended Datagram Congestion Control Protocol is suggested for multiple flows. This protocol will reduce congestion in Wireless Sensor Network. Keywords: WSN, Congestion control, Datagram, Packets, multimedia traffic, ELFN, Payload, CCID2, CCID3, TFRC. 1 Introduction WSN typically consists of a large number of tiny wireless sensor nodes (often referred to as nodes or motes) that are densely deployed [1]. Nodes measure some ambient conditions in the environment surrounding them. These measurements are, then, transformed into signals that can be processed to reveal some characteristics about the phenomenon. The data collected is routed to special nodes, called sink nodes (or Base Station, BS), typically in a multi-hop basis. Then, the sink node sends data to the user. Sensor networks have a wide range of applications in habitat observation, health monitoring, object tracking, battlefield sensing, etc. They are different from traditional wireless networks in many aspects.