@article{MAKHILLIJSC20149421204,
    title = {Energy Conserved Fault Tolerance Relay Nodes in Wireless Network},
    journal = {International Journal of Soft Computing},
    volume = {9},
    number = {4},
    pages = {200-206},
    year = {2014},
    issn = {1816-9503},
    doi = {ijscomp.2014.200.206},
    url = {https://makhillpublications.co/view-article.php?issn=1816-9503&doi=ijscomp.2014.200.206},
    author = {D. Satish and},
    keywords = {Wireless network,Two-Tier Network Model,energy alert,fault tolerance,mobile multi-hop relay network,level self-sufficient scheme,network re-entry delay},
    abstract = {The rapid development of wireless communications has permitted 
  to improve low-cost, low-energy sensor nodes each accomplished of sensing, processing 
  and communicating with neighboring nodes by means of wireless links. A Dual 
  Tired Network Model are planned to be proposed for relay placement problem. 
  Energy-alert and fault tolerance are two important design goals of large scale 
  wireless sensor network. Dual Tired Network Model formulate a constrained multi-inconsistent 
  linear programming to determine the location of the sensor nodes and data transmission 
  pattern. Initial tier, a linear network finds optimal placement strategies algebraically 
  using Consistent Assignment (CA) scheme. Through algebraic results, the optimal 
  node placement strategies provide a significant benefit to minimize the energy 
  alert total cost. In Dual Tired Network Model, second tier develops a Level 
  Self-sufficient (LS) scheme to create a solution for fault tolerance mechanism. 
  It also analysis the fake information sources that acted as storage nodes during 
  the failure of links to minimize the delay time. The two objectives studied 
  in the study are to minimize the energy consumption total cost and to develop 
  fault tolerant mechanism. A finite number of sensor or aggregation nodes in 
  a region with certain coverage requirement are provided to perform the experimental 
  evaluation. Various statistical parameters computed are compared with the existing 
  Mobile Multi-hop Relay (MMR) networks to obtain better results with 8.166% minimized 
  energy consumption in terms of cost, effective fault tolerant and minimal delay 
  occurrence during network re-entry.}
    }