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Venkadesh, R.
- Simulation of Integrated MAR in Wireless Network Architecture by using Higher-Level and Lower-Level Proxy Servers
Abstract Views :165 |
PDF Views:3
Authors
Affiliations
1 Vel Tech (Owned by RS trust), Chennai- 62, IN
2 Vel Tech (Owned by RS trust), Chennai-62, IN
3 Velammal Engineering College- Tifaccore Department, Chennai, IN
1 Vel Tech (Owned by RS trust), Chennai- 62, IN
2 Vel Tech (Owned by RS trust), Chennai-62, IN
3 Velammal Engineering College- Tifaccore Department, Chennai, IN
Source
Wireless Communication, Vol 3, No 6 (2011), Pagination: 407-412Abstract
The Higher-Level and Lower-Level Proxy servers is an effective solution to reduce Web traffic and integrated wireless network architecture using Proxy servers to support mobility management. The technique takes advantage of the existing functionalities of proxy servers to provide mobility support for applications such as Web browsing, HTTP and FTP, without modifying the IP protocol stack of the mobile host. The architecture uses proxy servers to force all packets originating from mobile hosts to a close-by mobility-aware router so that the latter can maintain active data connections during handoffs across different networks. By deploying multiple proxy and mobility-aware router pairs and by assigning mobile hosts to proxy servers dynamically, the proposed architecture provides efficient mobility management functionalities, and is inherently scalable. This paper describes performance and building simulation models for evaluating mobility of proxy servers. The basic idea of the proposed method is the system takes advantage of the existing proxy supports in network applications to maintain network connection during a handoff and to reduce Web traffic than existing scheme.Keywords
Destination Server, Higher-Level Proxy Server, Lower-Level Proxy Server, Mobile Aware Router, Mobile Host.- Wireless Signal Propagation Using Magnetic Induction in Underground Sensor Network
Abstract Views :180 |
PDF Views:3
Authors
R. Venkadesh
1,
R. Balaji
2
Affiliations
1 Vel Tech DR.RR & DR.SR Technical University, AP/ECE, Chennai-62, IN
2 Velammal Engineering College, Tifaccore Department, Chennai, IN
1 Vel Tech DR.RR & DR.SR Technical University, AP/ECE, Chennai-62, IN
2 Velammal Engineering College, Tifaccore Department, Chennai, IN
Source
Wireless Communication, Vol 2, No 1 (2010), Pagination:Abstract
The wireless underground sensor networks (WUSNs) and the terrestrial wireless sensor networks differ in the aspect of signal propagation medium. The underground sensor network is a challenging environment for wireless communications since the propagation medium consists of soil, rock and water. The former signal propagation techniques use the EM wave suffers from high path loss, dynamic channel condition and large antenna size. To overcome these disadvantages we go for a MI (Magnetic Induction) technique. Based on the channel analysis, the MI waveguide technique is used to reduce the high path loss. The MI transmission technique requires low operating frequencies and lesser power than the ordinary RF frequencies. But the lower operating frequencies requires high antenna size used to transmit and receive signals at 300 MHz .Based on the analysis we increase the transmission range to a larger extent than the existing range with the help of low antenna size. In this paper, we first provide a detailed analysis on the path loss and the bandwidth of the MI communication channel in underground environments. Then based on the analysis, we develop the MI waveguide technique for WUSNs, which can significantly reduce the path loss, enlarge the transmission range and achieve practical bandwidth for MI communication in underground environments. In particular, the MI transmitter and receiver are modeled as the primary coil and secondary coil of a transformer. Multiple factors are considered in the analysis, including the soil properties, coil size, the number of turns in the coil loop, coil resistance, operating frequency. The analysis shows that the ordinary MI systems have larger transmission range but lower bandwidth than the EM wave systems. However, neither the ordinary MI system nor the EM wave system is able to provide enough communication range for practical WUSNs applications. Motivated by this fact, we develop the MI waveguide technique to enlarge the communication range. In this case, some small coils are deployed between the transmitter and the receiver as relay points, which form a discontinuous waveguide. It shows that the MI transmission is not affected by soil type, composition, compaction, or moisture content, and requires less power and lower operating frequencies than RF transmission. However, the theoretical/experimental results show that the communication range is no more than 30 inches (0.76 m). Moreover, the bandwidth of the MI system is not considered in the paper.Keywords
Wireless Signal Propagation,the Wireless Underground Sensor Networks.- Simulation of AC Voltage Regulator in High Frequency Power System
Abstract Views :205 |
PDF Views:3
Authors
Affiliations
1 Vel Tech, Chennai-600062, IN
2 Department of ECE, Vel Tech DR. RR & DR. SR Technical University, Chennai-600062, IN
3 TVH Energy Resource (P) Ltd, Chennai, IN
4 Department of EEE, Chennai-600055, IN
5 Department of EEE, Vel Tech, Chennai-600062, IN
1 Vel Tech, Chennai-600062, IN
2 Department of ECE, Vel Tech DR. RR & DR. SR Technical University, Chennai-600062, IN
3 TVH Energy Resource (P) Ltd, Chennai, IN
4 Department of EEE, Chennai-600055, IN
5 Department of EEE, Vel Tech, Chennai-600062, IN