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89 results on '"Zafer, Murtaza"'

1. Online Placement of Multi-Component Applications in Edge Computing Environments

Author

Wang, Shiqiang, Zafer, Murtaza, and Leung, Kin K.

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Data Structures and Algorithms, Computer Science - Networking and Internet Architecture, Mathematics - Optimization and Control
Abstract

Mobile edge computing is a new cloud computing paradigm which makes use of small-sized edge-clouds to provide real-time services to users. These mobile edge-clouds (MECs) are located in close proximity to users, thus enabling users to seamlessly access applications running on MECs. Due to the co-existence of the core (centralized) cloud, users, and one or multiple layers of MECs, an important problem is to decide where (on which computational entity) to place different components of an application. This problem, known as the application or workload placement problem, is notoriously hard, and therefore, heuristic algorithms without performance guarantees are generally employed in common practice, which may unknowingly suffer from poor performance as compared to the optimal solution. In this paper, we address the application placement problem and focus on developing algorithms with provable performance bounds. We model the user application as an application graph and the physical computing system as a physical graph, with resource demands/availabilities annotated on these graphs. We first consider the placement of a linear application graph and propose an algorithm for finding its optimal solution. Using this result, we then generalize the formulation and obtain online approximation algorithms with polynomial-logarithmic (poly-log) competitive ratio for tree application graph placement. We jointly consider node and link assignment, and incorporate multiple types of computational resources at nodes., Comment: This is the author's version of the paper accepted for publication in IEEE Access

Published
2016
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2. Dynamic Service Migration in Mobile Edge Computing Based on Markov Decision Process

Author

Wang, Shiqiang, Urgaonkar, Rahul, Zafer, Murtaza, He, Ting, Chan, Kevin, and Leung, Kin K.

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Networking and Internet Architecture, Mathematics - Optimization and Control
Abstract

In mobile edge computing, local edge servers can host cloud-based services, which reduces network overhead and latency but requires service migrations as users move to new locations. It is challenging to make migration decisions optimally because of the uncertainty in such a dynamic cloud environment. In this paper, we formulate the service migration problem as a Markov Decision Process (MDP). Our formulation captures general cost models and provides a mathematical framework to design optimal service migration policies. In order to overcome the complexity associated with computing the optimal policy, we approximate the underlying state space by the distance between the user and service locations. We show that the resulting MDP is exact for uniform one-dimensional user mobility while it provides a close approximation for uniform two-dimensional mobility with a constant additive error. We also propose a new algorithm and a numerical technique for computing the optimal solution which is significantly faster than traditional methods based on standard value or policy iteration. We illustrate the application of our solution in practical scenarios where many theoretical assumptions are relaxed. Our evaluations based on real-world mobility traces of San Francisco taxis show superior performance of the proposed solution compared to baseline solutions., Comment: Journal version

Published
2015

3. Mobility-Induced Service Migration in Mobile Micro-Clouds

Author

Wang, Shiqiang, Urgaonkar, Rahul, He, Ting, Zafer, Murtaza, Chan, Kevin, and Leung, Kin K.

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Networking and Internet Architecture, Mathematics - Optimization and Control
Abstract

Mobile micro-cloud is an emerging technology in distributed computing, which is aimed at providing seamless computing/data access to the edge of the network when a centralized service may suffer from poor connectivity and long latency. Different from the traditional cloud, a mobile micro-cloud is smaller and deployed closer to users, typically attached to a cellular basestation or wireless network access point. Due to the relatively small coverage area of each basestation or access point, when a user moves across areas covered by different basestations or access points which are attached to different micro-clouds, issues of service performance and service migration become important. In this paper, we consider such migration issues. We model the general problem as a Markov decision process (MDP), and show that, in the special case where the mobile user follows a one-dimensional asymmetric random walk mobility model, the optimal policy for service migration is a threshold policy. We obtain the analytical solution for the cost resulting from arbitrary thresholds, and then propose an algorithm for finding the optimal thresholds. The proposed algorithm is more efficient than standard mechanisms for solving MDPs., Comment: in Proc. of IEEE MILCOM 2014, Oct. 2014

Published
2015
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4. Dynamic Service Placement for Mobile Micro-Clouds with Predicted Future Costs

Author

Wang, Shiqiang, Urgaonkar, Rahul, He, Ting, Chan, Kevin, Zafer, Murtaza, and Leung, Kin K.

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Networking and Internet Architecture, Mathematics - Optimization and Control
Abstract

Mobile micro-clouds are promising for enabling performance-critical cloud applications. However, one challenge therein is the dynamics at the network edge. In this paper, we study how to place service instances to cope with these dynamics, where multiple users and service instances coexist in the system. Our goal is to find the optimal placement (configuration) of instances to minimize the average cost over time, leveraging the ability of predicting future cost parameters with known accuracy. We first propose an offline algorithm that solves for the optimal configuration in a specific look-ahead time-window. Then, we propose an online approximation algorithm with polynomial time-complexity to find the placement in real-time whenever an instance arrives. We analytically show that the online algorithm is $O(1)$-competitive for a broad family of cost functions. Afterwards, the impact of prediction errors is considered and a method for finding the optimal look-ahead window size is proposed, which minimizes an upper bound of the average actual cost. The effectiveness of the proposed approach is evaluated by simulations with both synthetic and real-world (San Francisco taxi) user-mobility traces. The theoretical methodology used in this paper can potentially be applied to a larger class of dynamic resource allocation problems., Comment: This is the author's version of the paper accepted for publication in the IEEE Transactions on Parallel and Distributed Systems

Published
2015
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7. Introduction

Author

Berry, Randall, Modiano, Eytan, Zafer, Murtaza, Berry, Randall, Modiano, Eytan, and Zafer, Murtaza

Published
2012
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11. Optimal rate control for delay-constrained data transmission over a wireless channel

Author

Zafer, Murtaza and Modiano, Eytan

Subjects
Wireless technology, Mobile communication systems -- Research, Data communications -- Research, Wireless communication systems -- Research
Abstract

We study energy-efficient transmission of data with deadline constraints over a time-varying channel. Specifically, the system model consists of a wireless transmitter with controllable transmission rate, time-varying and stochastic channel state, and strict delay constraints on the packets in the queue. While the transmitter can control the rate, the transmission power required depends on the chosen rate and the prevailing channel condition. The objective is to obtain a rate control policy that serves the data within the deadline constraints while minimizing the total energy expenditure. Toward this end, we first introduce the canonical problem of transmitting B units of data by deadline T over a Markov fading channel, and obtain the optimal policy for it using continuous-time stochastic control theory. Using a novel cumulative curves methodology and a decomposition approach, we extend the above setup to consider extensions involving variable deadlines on the packets. Finally, utilizing the analysis we present a heuristic policy for the case of arbitrary packet arrivals to the queue with individual deadline constraints, and give illustrative simulation results for its performance. Index Terms--Delay, energy, quality of service, stochastic control, transmission rate, wireless.

Published
2008

14. Introduction

Author

Berry, Randall, primary, Modiano, Eytan, additional, and Zafer, Murtaza, additional

Published
2012
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20. A Framework for the Inference of Sensing Measurements Based on Correlation.

Author

SILVESTRI, SIMONE, URGAONKAR, RAHUL, ZAFER, MURTAZA, and BONG JUN KO

Abstract

Sensor networks are commonly adopted to collect a variety of measurements in indoor and outdoor settings. However, collecting such measurements from every node in the network, although providing high accuracy and resolution of the phenomena of interest, may easily cause sensors' battery depletion. In this article, we show that measurement correlation can be successfully exploited to reduce the amount of data collected in the network without significantly sacrificing the monitoring accuracy. In particular, we propose an online adaptive measurement technique with which a subset of nodes are dynamically chosen as monitors while the measurements of the remaining nodes are estimated using the computed correlations.We propose an estimation framework based on jointly Gaussian distributed random variables, and we formulate an optimization problem to select the monitors under a total cost constraint. We show that the problem is NP-Hard and propose three efficient heuristics. We also develop statistical approaches that automatically switch between learning and estimation phases to take into account the variability occurring in real networks. Simulations carried out on real-world traces show that our approach outperforms previous solutions based on compressed sensing, and it can be successfully applied to the real application of solar irradiance prediction of photovoltaics systems. [ABSTRACT FROM AUTHOR]

Published
2019
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25. Channel assignment algorithms and blocking probability analysis for connection-oriented traffic in wireless networks

Author

Eytan Modiano., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., Zafer, Murtaza Abbasali, 1979, Eytan Modiano., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., and Zafer, Murtaza Abbasali, 1979

Abstract

Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2003., Vita., Includes bibliographical references (leaves 103-105)., by Murtaza Abbasali Zafer., S.M.

Published
2014

27. A Calculus Approach to Energy-Efficient Data Transmission With Quality-of-Service Constraints

Author

Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Modiano, Eytan H., Zafer, Murtaza A., Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Modiano, Eytan H., and Zafer, Murtaza A.

Abstract

Transmission rate adaptation in wireless devices provides a unique opportunity to trade off data service rate with energy consumption. In this paper, we study optimal rate control to minimize transmission energy expenditure subject to strict deadline or other quality-of-service (QoS) constraints. Specifically, the system consists of a wireless transmitter with controllable transmission rate and with strict QoS constraints on data transmission. The goal is to obtain a rate-control policy that minimizes the total transmission energy expenditure while ensuring that the QoS constraints are met. Using a novel formulation based on cumulative curves methodology, we obtain the optimal transmission policy and show that it has a simple and appealing graphical visualization. Utilizing the optimal ldquoofflinerdquo results, we then develop an online transmission policy for an arbitrary stream of packet arrivals and deadline constraints, and show, via simulations, that it is significantly more energy-efficient than a simple head-of-line drain policy. Finally, we generalize the optimal policy results to the case of time-varying power-rate functions., National Science Foundation (U.S.) (NSF ITR Grant CCR-0325401), United States. Defense Advanced Research Projects Agency (University of Illinois Grant F49620-02-1-0325), United States. Office of Naval Research (ONR Grant N000140610064), United States. Army Research Office (ARO Muri Grant W911NF-08-1-0238)

Published
2011

28. Minimum Energy Transmission Over a Wireless Channel With Deadline and Power Constraints

Author

Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Modiano, Eytan H., Zafer, Murtaza, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Modiano, Eytan H., and Zafer, Murtaza

Abstract

We consider optimal rate-control for energy-efficient transmission of data, over a time-varying channel, with packet-deadline constraints. Specifically, the problem scenario consists of a wireless transmitter with B units of data that must be transmitted by deadline T over a fading channel. The transmitter can control the transmission rate over time and the required instantaneous power depends on the chosen rate and the present channel condition, with limits on short-term average power consumption. The objective is to obtain the optimal rate-control policy that minimizes the total energy expenditure while ensuring that the deadline constraint is met. Using a continuous-time stochastic control formulation and a Lagrangian duality approach, we explicitly obtain the optimal policy and show that it possesses a very simple and intuitive form. Finally, we present an illustrative simulation example comparing the energy costs of the optimal policy with the full power policy., National Science Foundation (U.S.) (ITR grant CCR-0325401), United States. Defense Advanced Research Projects Agency, United States. Air Force Office of Scientific Research. Multidisciplinary University Research Initiative (Grant F49620-02-1-0325), United States. Office of Naval Research (Grant N000140610064), United States. Army Research Office. Multidisciplinary University Research Initiative (Grant W911NF-08-1-0238)

Published
2011

44. Optimal bidding in spot instance market.

Author

Yang Song, Zafer, Murtaza, and Kang-Won Lee

Abstract

Amazon introduced Spot Instance Market to utilize the idle resources of Amazon Elastic Compute Cloud (EC2) more efficiently. The price of a spot instance changes dynamically according to the current supply and demand for cloud resources. Users can bid for a spot instance and the job request will be granted if the current spot price falls below the bid, whereas the job will be terminated if the spot price exceeds the bid. In this paper, we investigate the problem of designing a bidding strategy from a cloud service broker's perspective, where the cloud service broker accepts job requests from cloud users, and leverages the opportunistic yet less expensive spot instances for computation in order to maximize its own profit. In this context, we propose a profit aware dynamic bidding (PADB) algorithm, which observes the current spot price and selects the bid adaptively to maximize the time average profit of the cloud service broker. We show that our bidding strategy achieves a near-optimal solution, i.e., (1−∈) of the optimal solution to the profit maximization problem, where ∈ can be arbitrarily small. The proposed dynamic bidding algorithm is self-adaptive and requires no a priori statistical knowledge on the distribution of random job sizes from cloud users. [ABSTRACT FROM PUBLISHER]

Published
2012
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