Aigaion: RACTI / RU1 Technical Report Series (Web Based)

[RACTI-RU1-2009-46] Kinalis, Athanasios and Nikoletseas, Sotiris, Adaptive Data Dissemination in Mobile Sensor Networks, in: Interconnection Networks (JOIN), 2009.
Abstract: Motivated by emerging applications, we consider sensor networks where the sensors themselves (not just the sinks) are mobile. Furthermore, we focus on mobility scenarios characterized by heterogeneous, highly changing mobility roles in the network. To capture these high dynamics of diverse sensory motion we propose a novel network parameter, the mobility level, which, although simple and local, quite accurately takes into account both the spatial and speed characteristics of motion. We then propose adaptive data dissemination protocols that use the mobility level estimation to optimize performance, by basically exploiting high mobility (redundant message ferrying) as a cost-effective replacement of flooding, e.g. the sensors tend to dynamically propagate less data in the presence of high mobility, while nodes of high mobility are favored for moving data around. These dissemination schemes are enhanced by a distance-sensitive probabilistic message flooding inhibition mechanism that further reduces communication cost, especially for fast nodes of high mobility level, and as distance to data destination decreases. Our simulation findings demonstrate significant performance gains of our protocols compared to non-adaptive protocols, i.e. adaptation increases the success rate and reduces latency (even by 15%) while at the same time significantly reducing energy dissipation (in most cases by even 40%). Also, our adaptive schemes achieve significantly higher message delivery ratio and satisfactory energy-latency trade-offs when compared to flooding when sensor nodes have limited message queues.
[RACTI-RU1-2008-4] Chatzigiannakis, Ioannis, Kinalis, Athanasios and Nikoletseas, Sotiris, Adaptive Energy Management for Incremental Deployment of Heterogeneous Wireless Sensors, in: Theory of Computing Systems, volume 42, number 1, pages 42-72, ISSN 1432-4350, 2008. [DOI]
Abstract: We introduce a new modelling assumption for wireless sensor networks, that of node redeployment (addition of sensor devices during protocol evolution) and we extend the modelling assumption of heterogeneity (having sensor devices of various types). These two features further increase the highly dynamic nature of such networks and adaptation becomes a powerful technique for protocol design. Under these modelling assumptions, we design, implement and evaluate a new power conservation scheme for efficient data propagation. Our scheme is adaptive: it locally monitors the network conditions (density, energy) and accordingly adjusts the sleep-awake schedules of the nodes towards improved operation choices. The scheme is simple, distributed and does not require exchange of control messages between nodes. Implementing our protocol in software we combine it with two well-known data propagation protocols and evaluate the achieved performance through a detailed simulation study using our extended version of the network simulator ns-2. We focus on highly dynamic scenarios with respect to network density, traffic conditions and sensor node resources. We propose a new general and parameterized metric capturing the trade-offs between delivery rate, energy efficiency and latency. The simulation findings demonstrate significant gains (such as more than doubling the success rate of the well-known Directed Diffusion propagation protocol) and good trade-offs achieved. Furthermore, the redeployment of additional sensors during network evolution and/or the heterogeneous deployment of sensors, drastically improve (when compared to ``equal total power" simultaneous deployment of identical sensors at the start) the protocol performance (i.e. the success rate increases up to four times} while reducing energy dissipation and, interestingly, keeping latency low).
[RACTI-RU1-2012-7] Amaxilatis, Dimitrios, Oikonomou, Georgios and Chatzigiannakis, Ioannis, Adaptive Neighbor Discovery for Mobile and Low Power Wireless Sensor Networks, MSWiM�12, Paphos, Cyprus, 2012.
Abstract: Wireless Sensor Networks are by nature highly dynamic and communication between sensors is completely ad hoc, especially when mobile devices are part of the setup. Numerous protocols and applications proposed for such networks operate on the assumption that knowledge of the neighborhood is a priori available to all nodes. As a result, WSN deployments need to use or implement from scratch a neighborhood discovery mechanism. In this work we present a new protocol based on adaptive periodic beacon exchanges. We totally avoid continuous beaconing by adjusting the rate of broadcasts using the concept of consistency over the understanding of neighborhood that nearby devices share. We propose, implement and evaluate our adaptive neighborhood discovery protocol over our experimental testbed and using large scale simulations. Our results indicate that the new protocol operates more eciently than existing reference implementations while it provides valid information to applications that use it. Extensive performance evaluation indicates that it successfully reduces generated network traffic by 90% and increases network lifetime by 20% compared to existing mechanisms that rely on continuous beaconing.
[RACTI-RU1-2008-30] Kinalis, Athanasios and Nikoletseas, Sotiris, Adaptive Redundancy for Data Propagation Exploiting Dynamic Sensory Mobility, 2008.
Abstract: Motivated by emerging applications, we consider sensor networks where the sensors themselves (not just the sinks) are mobile. Furthermore, we focus on mobility scenarios characterized by heterogeneous, highly changing mobility roles in the network. To capture these high dynamics of diverse sensory motion we propose a novel network parameter, the mobility level, which, although simple and local, quite accurately takes into account both the spatial and speed characteristics of motion. We then propose adaptive data dissemination protocols that use the mobility level estimation to optimize performance, by basically exploiting high mobility (redundant message ferrying) as a cost-effective replacement of flooding, e.g., the sensors tend to dynamically propagate less data in the presence of high mobility, while nodes of high mobility are favored for moving data around. These dissemination schemes are enhanced by a distance-sensitive probabilistic message flooding inhibition mechanism that further reduces communication cost, especially for fast nodes of high mobility level, and as distance to data destination decreases. Our simulation findings demonstrate significant performance gains of our protocols compared to non-adaptive protocols, i.e., adaptation increases the success rate and reduces latency (even by 15\%) while at the same time significantly reducing energy dissipation (in most cases by even 40\%). Also, our adaptive schemes achieve significantly higher message delivery ratio and satisfactory energy-latency trade-offs when compared to flooding when sensor nodes have limited message queues.
[RACTI-RU1-2008-31] Kinalis, Athanasios and Nikoletseas, Sotiris, Adaptive Redundancy for Data Propagation Exploiting Dynamic Sensory Mobility, in: 11th ACM International Conference on Modeling, Analysis and Simulation of Wireless and Mobile Systems, pages 1-8, 2008.
Abstract: Motivated by emerging applications, we consider sensor networks where the sensors themselves (not just the sinks) are mobile. We focus on mobility scenarios characterized by heterogeneous, highly changing mobility roles in the network. To capture these high dynamics we propose a novel network parameter, the mobility level, which, although simple and local, quite accurately takes into account both the spatial and speed characteristics of motion. We then propose adaptive data dissemination protocols that use the mobility level estimation to improve performance. By basically exploiting high mobility (redundant message ferrying) as a cost-effective replacement of flooding, e.g., the sensors tend to dynamically propagate less data in the presence of high mobility, while nodes of high mobility are favored for moving data around. These dissemination schemes are enhanced by a distance-sensitive probabilistic message flooding inhibition mechanism that further reduces communication cost, especially for fast nodes of high mobility level, and as distance to data destination decreases. Our simulation findings demonstrate significant performance gains of our protocols compared to non-adaptive protocols, i.e., adaptation increases the success rate and reduces latency (even by 15\%) while at the same time significantly reducing energy dissipation (in most cases by even 40\%). Also, our adaptive schemes achieve significantly higher message delivery ratio and satisfactory energy-latency trade-offs when compared to flooding when sensor nodes have limited message queues.
[RACTI-RU1-2006-35] Chatzigiannakis, Ioannis, Kinalis, Athanasios and Nikoletseas, Sotiris, Adaptive Techniques for Proactive Collision Avoidance for Multi-path Data Propagation in Wireless Sensor Networks, in: Performance Evaluation, volume 63, number 11, pages 1074-1093, 2006. [DOI]
Abstract: Data propagation in wireless sensor networks can be performed either by hop-by-hop single transmissions or by multi-path broadcast of data. Although several energy-aware MAC layer protocols exist that operate very well in the case of single point-to-point transmissions, none is especially designed and suitable for multiple broadcast transmissions. The key idea of our protocols is the passive monitoring of local network conditions and the adaptation of the protocol operation accordingly. The main contribution of our adaptive method is to proactively avoid collisions by implicitly and early enough sensing the need for collision avoidance. Using the above ideas, we design, implement and evaluate three different, new strategies for proactive adaptation. We show, through a detailed and extended simulation evaluation, that our parameter-based family of protocols for multi-path data propagation significantly reduce the number of collisions and thus increase the rate of successful message delivery (to above 90%) by achieving satisfactory trade-offs with the average propagation delay. At the same time, our protocols are shown to be very energy efficient, in terms of the average energy dissipation per delivered message.
[RACTI-RU1-2009-49] Boukerche, Azzedine, Efstathiou, Dionysios and Nikoletseas, Sotiris, Adaptive, Direction-Aware Data Dissemination for Diverse Sensor Mobility, in: 7th ACM/IEEE International Symposium on Mobility Management and Wireless Access Protocols (MobiWac 2009), ACM Press, MobiWac, Tenerife, Canary Islands, 2009.
Abstract: We consider sensor networks where the sensor nodes are attached on entities that move in a highly dynamic, heterogeneous manner. To capture this mobility diversity we introduce a new network parameter, the direction-aware mobility level, which measures how fast and close each mobile node is expected to get to the data destination (the sink). We then provide local, distributed data dissemination protocols that adaptively exploit the node mobility to improve performance. In particular, "high" mobility is used as a low cost replacement for data dissemination (due to the ferrying of data), while in the case of "low" mobility either a) data propagation redundancy is increased (when highly mobile neighbors exist) or b) long-distance data transmissions are used (when the entire neighborhood is of low mobility) to accelerate data dissemination towards the sink. An extensive performance comparison to relevant methods from the state of the art demonstrates signicant improvements i.e. latency is reduced by even 4 times while keeping energy dissipation and delivery success at very satisfactory levels.
[RACTI-RU1-2013-24] Angelopoulos, Constantinos Marios, Nikoletseas, Sotiris and Raptis, Theofanis, Adaptive, limited knowledge wireless recharging in sensor networks, pages 65-72, MOBIWAC 2013, 2013.
Abstract: We investigate the problem of ecient wireless energy recharging in Wireless Rechargeable Sensor Networks (WRSNs). In such networks a special mobile entity (called the Mobile Charger) traverses the network and wirelessly replenishes the energy of sensor nodes. In contrast to most current approaches, we envision methods that are distributed, adaptive and use limited network information. We propose three new, alternative protocols for ecient recharging, addressing key issues which we identify, most notably (i) to what extent each sensor should be recharged (ii) what is the best split of the total energy between the charger and the sensors and (iii) what are good trajectories the MC should follow. One of our protocols ( LRP ) performs some distributed, limited sampling of the network status, while another one ( RTP ) reactively adapts to energy shortage alerts judiciously spread in the network. As detailed simulations demonstrate, both protocols signicantly outperform known state of the art methods, while their performance gets quite close to the performance of the global knowledge method ( GKP ) we also provide, especially in heterogeneous network deployments.
[RACTI-RU1-2005-19] Chatzigiannakis, Ioannis, Kinalis, Athanasios and Nikoletseas, Sotiris, An Adaptive Power Conservation Scheme for Heterogeneous Wireless Sensors, in: 17th ACM Symposium on Parallelism in Algorithms and Architectures (SPAA 2005), pages 96-105, ACM Press, ACM, Las Vegas, NV, USA, 2005.
Abstract: We introduce a new modelling assumption in wireless sensor networks, that of node redeployment (addition of sensor devices during the protocol evolution) and we extend the modelling assumption of heterogeneity (having sensor devices of various types). These two features further increase the highly dynamic nature of such networks and adaptation becomes a powerful technique for protocol design. Under this model, we design, implement and evaluate a power conservation scheme for efficient data propagation. Our protocol is adaptive: it locally monitors the network conditions (density, energy) and accordingly adjusts the sleep-awake schedules of the nodes towards best operation choices. Our protocol operates does not require exchange of control messages between nodes to coordinate.Implementing our protocol we combine it with two well-known data propagation protocols and evaluate the achieved performance through a detailed simulation study using our extended version of Ns2. We focus in highly dynamic scenarios with respect to network density, traffic conditions and sensor node resources. We propose a new general and parameterized metric capturing the trade-off between delivery rate, energy efficiency and latency. The simulation findings demonstrate significant gains (such as more than doubling the success rate of the well-known Directed Diffusion propagation paradigm) and good trade-offs. Furthermore, redeployment of sensors during network evolution and/or heterogeneous deployment of sensors drastically improve (when compared to equal total "power" simultaneous deployment of identical sensors at the start) the protocol performance (the success rate increases up to four times while reducing energy dissipation and, interestingly, keeping latency low).
[RACTI-RU1-2011-68] Boukerche, Azzedine, Efstathiou, Dionysios, Nikoletseas, Sotiris and Raptopoulos, Christoforos, Close-to-optimal Energy Balanced Data Propagation via Limited, Local Network Density Information, in: 14th ACM International Symposium on Modeling, Analysis and Simulation of Wireless and Mobile Systems, ACM Press, MSWiM 2011, 2011.
Abstract: We study the problem of energy-balanced data propagation in wireless sensor networks. The energy balance property is crucial for maximizing the time the network is functional, by avoiding early energy depletion of a large portion of sensors. We propose a distributed, adaptive data propagation algorithm that exploits limited, local network density information for achieving energy-balance while at the same time minimizing energy dissipation. We investigate both uniform and heterogeneous sensor placement distributions. By a detailed experimental evaluation and comparison with well-known energy-balanced protocols, we show that our density-based protocol improves energy efficiency signicantly while also having better energy balance properties. Furthermore, we compare the performance of our protocol with a centralized, o-line optimum solution derived by a linear program which maximizes the network lifetime and show that it achieves near-optimal performance for uniform sensor deployments.
[RACTI-RU1-2005-17] Chatzigiannakis, Ioannis, Kinalis, Athanasios and Nikoletseas, Sotiris, Power Conservation Schemes for Energy Efficient Data Propagation in Heterogeneous Wireless Sensor Networks, in: 38th Annual ACM/IEEE Simulation Symposium (ANSS), pages 60-71, IEEE Computer Society, SCS, San Diego, CA, USA, 2005. [DOI]
Abstract: We propose, implement and evaluate new energy conservation schemes for efficient data propagation in wireless sensor networks. Our protocols are adaptive, i.e. locally monitor the network conditions and accordingly adjust towards optimal operation choices. This dynamic feature is particularly beneficial in heterogeneous settings and in cases of redeployment of sensor devices in the network area. We implement our protocols and evaluate their performance through a detailed simulation study using our extended version of ns-2. In particular we combine our schemes with known communication paradigms. The simulation findings demonstrate significant gains and good trade-offs in terms of delivery success, delay and energy dissipation.
[RACTI-RU1-2006-80] Nikoletseas, Sotiris, Power-Aware Data Dissemination Protocols for Wireless Sensor Networks, in: 14th International Workshop on Parallel and Distributed Real-time Systems (WPDRTS 2006), 2006.
Abstract: Recent rapid technological developments have led to the development of tiny, low-power, low-cost sensors. Such devices integrate sensing, limited data processing and communication capabilities.The effective distributed collaboration of large numbers of such devices can lead to the efficient accomplishment of large sensing tasks. This talk focuses on several aspects of energy efficiency. Two protocols for data propagation are studied: the first creates probabilistically optimized redundant data transmissions to combine energy efficiency with fault tolerance, while the second guarantees (in a probabilistic way) the same per sensor energy dissipation, towards balancing the energy load and prolong the lifetime of the network. A third protocol (in fact a power saving scheme) is also presented, that directly and adaptively affects power dissipation at each sensor. This �lower level� scheme can be combined with data propagation protocols to further improve energy efficiency.
[RACTI-RU1-2009-47] Leone, Pierre, Nikoletseas, Sotiris and Rolim, Jose, Stochastic Models and Adaptive Algorithms for Energy Balance in Sensor Networks, in: Theory of Computing Systems, 2009.
Abstract: We consider the important problem of energy balanced data propagation in wireless sensor networks and we extend and generalize previous works by allowing adaptive energy assignment. We consider the data gathering problem where data are generated by the sensors and must be routed toward a unique sink. Sensors route data by either sending the data directly to the sink or in a multi-hop fashion by delivering the data to a neighbouring sensor. Direct and neighbouring transmissions require different levels of energy consumption. Basically, the protocols balance the energy consumption among the sensors by computing the adequate ratios of direct and neighbouring transmissions. An abstract model of energy dissipation as a random walk is proposed, along with rigorous performance analysis techniques. Two efficient distributed algorithms are presented and analysed, by both rigorous means and simulation. The first one is easy to implement and fast to execute. The protocol assumes that sensors know a-priori the rate of data they generate. The sink collects and processes all these information in order to compute the relevant value of the protocol parameter. This value is transmitted to the sensors which individually compute their optimal ratios of direct and neighbouring transmissions. The second protocol avoids the necessary a-priori knowledge of the data rate generated by sensors by inferring the relevant information from the observation of the data paths. Furthermore, this algorithm is based on stochastic estimation methods and is adaptive to environmental changes.