eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2831
2844
10.24200/sci.2016.3993
3993
A Survey of Key Pre-Distribution and Overlay Routing in Unstructured Wireless Networks
M. Gharib
gharib@ipm.ir
1
H. Yousefi’zadeh
hyousefi@uci.edu
2
A. Movaghar
movaghar@sharif.edu
3
Department of Computer Science, Institute for Research in Fundamental Sciences, Tehran, Iran
Center for Pervasive Communications and Computing, University of California Irvine
Department of Computer Engineering, Sharif University of Technology, Tehran, Iran
Unstructured wireless networks such as mobile ad hoc networks and wireless sensor networks have been rapidly growing in the past decade. Security is known as a challenging issue in such networks in which there is no fixed infrastructure or central trusted authority. Further, node limitations in processing power, storage, and energy consumption add further complexity to addressing security in such networks. While cryptography has proven as an effective solution capable of satisfying most network security requirements, it requires the use of efficient key pre-distribution algorithms compatible with the limitation of unstructured wireless networks. Typically, a key pre-distribution algorithm forms a cryptographic overlay layer above the network routing layer and as such introduces the need for relying on two layers of routing for secure delivery of information. In this paper, we conduct a categorical review of key pre-distribution methods for unstructured wireless networks. We also compare different key pre-distribution schemes in terms of performance and security strength. Finally, we provide an overview of recent overlay routing algorithms relying on key pre-distribution.
http://scientiairanica.sharif.edu/article_3993_3d962e96c4ac7aa69d610aa71c18bfd2.pdf
Security
Wireless Networks
Cryptography
Key Pre-Distribution
Overlay Routing
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2845
2861
10.24200/sci.2016.3994
3994
Survey of Bandgap and Non-bandgap based Voltage Reference Techniques
Vinayak Hande
vinayak.hande@iitb.ac.in
1
Maryam Shojaei Baghini
mshojaei@ee.iitb.ac.in
2
Department of Electrical Engineering, Indian Institute of Technology (IIT)-Bombay, Mumbai, MH, India
Department of Electrical Engineering, Indian Institute of Technology (IIT)-Bombay, Mumbai, MH, India
The design challenges of voltage reference generators in CMOS technology have increased over the years in low voltage low power CMOS integrated circuits constituting analog, digital and mixed-signal modules. The emergence of hand-held power autonomous devices push the power consumption limit to nW regime. Along with these confrontations, limited full scale range of data converters at low supply levels demands accurate reference voltage generators. This paper reviews the allied design challenges and discusses the evolved methodologies to tackle them. This paper also prominently retrospect the sub -1V voltage reference topologies presented in the literature along with classic bandgap based voltage reference topologies. Non- bandgap (only CMOS) based reference architectures are proven to be area and power efficient but always have to be accompanied with auxiliary on/off chip trimming mechanism for high accuracy. We also provide insightful analysis of the voltage reference topologies, required by the designers.
http://scientiairanica.sharif.edu/article_3994_662e80335f901210ed94ab381405fac2.pdf
bandgap
sub -1V
survey
temperature coefficient
voltage reference
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2862
2873
10.24200/sci.2016.3995
3995
Grid modernization for enhancing the resilience, reliability, economics, sustainability, and security of electricity grid in an uncertain environment
M. Shahidehpour
1
M. Fotuhi-Friuzabad
fotuhi@shairf.edu
2
Center of Excellence in Power System Control and Management, Department of Electrical Engineering, Sharif University of Technology, Tehran, P.O. Box 11365-11155, Iran
Center of Excellence in Power System Control and Management, Department of Electrical Engineering, Sharif University of Technology, Tehran, P.O. Box 11365-11155, Iran
This paper reviews the merits of modernizing the power grid and discusses the way electric utilities in various countries are directing their practices toward oering enhanced sustainability, reliability, resilience, security, and economics to their respective consumers. The modernization of the electricity grid, which has evolved as the brainchild of electricity restructuring, has been made all the more urgent by the virtually pervasive dependence of modern lives on a reliable, clean, and secure supply of aordable electricity. The electric utility industry restructuring, which has staged many institutional, regulatory, and business models, has enabled the modern electricity grid to take full advantage of a range of available energy sources and modern technologies pertaining to prosumers and transactive energy, renewable supply, storage, energy eciency, climate change and carbon capture, electrication of the transportation industry, microgrids and resilience, and large fossil units that have helped the electric utility industry meet its global objectives. Understanding the dynamics of grid modernization, which can oer a clear appreciation for the use of innovation in electric power systems, and the impact that grid modernization will have on individual lives, is among the issues which will be discussed in this paper.
http://scientiairanica.sharif.edu/article_3995_77c5d9c2a230615027e0eb273d9bb8f9.pdf
Grid modernization
Smart grid
Reliability
Rresiliency
Security
Economics
Distributed supply technology
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2874
2880
10.24200/sci.2016.3996
3996
Comment on Jackson’s analysis of electric charge quantizationdue to interaction with Dirac’s magnetic monopole
Masud Mansuripur
masud@optics.arizona.edu
1
College of Optical Sciences, The University of Arizona, Tucson, Arizona 85721
In J.D. Jackson’s Classical Electrodynamics textbook, the analysis of Dirac’s charge quantization condition in the presence of a magnetic monopole has a mathematical omission and an all too brief physical argument that might mislead some students. This paper presents a detailed derivation of Jackson’s main result, explains the significance of the missing term, and highlights the close connection between Jackson’s findings and Dirac’s original argument
http://scientiairanica.sharif.edu/article_3996_849f1396b088266356de2d5c4439b2b0.pdf
Magnetic monopole
Dirac monopole
Electric charge quantization
Vector potential vorticity
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2881
2890
10.24200/sci.2016.3997
3997
Wide-band modeling of modular multilevel converters using extended-frequency dynamic phasors
S. Rajesvaran
1
S. Filizadeh
2
Department of Electrical and Computer Engineering, University of Manitoba,75A Chancellor's Circle, Winnipeg, MB R3T 5V6, Canada
Department of Electrical and Computer Engineering, University of Manitoba,75A Chancellor's Circle, Winnipeg, MB R3T 5V6, Canada
This paper presents a model for a Modular Multilevel Converter (MMC) using extended-frequency dynamic phasors. The model is based upon a series of harmonicfrequency representations that are obtained for the fundamental and dominant harmonic components. Depending on the requirements of the study to be conducted and the desired level of model accuracy, a low-order model (i.e., average-value) or an arbitrarily wideband model may be constructed. The paper describes the principles of modeling using extended-frequency dynamic phasors, and applies them to an MMC connected to a power system represented using a Thevenin equivalent. The model contains details of the MMC's control system including its high-level control circuitry, as well as voltage balancing and synchronization components. The developed model is then validated by comparing it against a fully-detailed electromagnetic transient (EMT) simulation model developed in PSCAD/EMTDC simulator. Comparisons are made to establish the accuracy of the model (both its low-order and wide-band variants) and to assess the computational advantages it oers compared to conventional EMT models.
http://scientiairanica.sharif.edu/article_3997_ed14c6971db50f6a550c5c6344590624.pdf
Modular Multilevel Converter (MMC)
Voltage-Source Converter (VSC)
High-Voltage Direct Current (HVDC)
Electromagnetic transient (EMT)
Dynamic phasors
Modeling
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2891
2897
10.24200/sci.2016.3998
3998
Families of communication architectures for data centers and parallel processing derived by switching network dilation
B. Parhami
1
Department of Electrical & Computer Engineering, University of California, Santa Barbara, CA 93106-9560, USA
Network dilation is a way of oering system families, at a range of sizes and computational powers, which share an underlying communication architecture and routing algorithm. We consider indirect networks that connect processing nodes via intermediate switch nodes. In the simplest such indirect networks, there is a switching network of some regular topology, where each switch is connected to d other switches and to exactly one processing node. A variant, which we adopt here because it is more robust in the sense of not losing any processing capability to single-switch failures, is the use of 2-port processing nodes that connect to two neighboring switches. This alternate architecture also has the advantage of increasing the number of processing nodes from n to (d=2)n with a factorof- 2 increase in internode distances. A k-dilated version of the latter architecture replaces each processing node with a path network (linear array) of length k, thus growing the network size to k(d=2)n and also further increasing internode distances. In this paper, we study topological and performance attributes of such dilated network architectures, proving general theorems about worst-case and average internode distances and deriving the routing algorithm from that of the underlying switch network.
http://scientiairanica.sharif.edu/article_3998_3a600060a373a80b1783b49951394031.pdf
Communication
Graph theory
Interconnection network
Parallel processing
Routing algorithm
Symmetric network
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2898
2907
10.24200/sci.2016.3999
3999
Crosstalk Reduction in Hybrid Quantum-Classical Networks
Sima Bahrani
si.bahrani@ee.sharif.edu
1
Mohsen Razavi
m.razavi@leeds.ac.uk
2
Jawad A. Salehi
jasalehi@sharif.edu
3
Electrical Engineering Department, Sharif University of Technology, Tehran, Iran
School of Electronic and Electrical Engineering, University of Leeds, Leeds, LS2 9JT, UK
Electrical Engineering Department, Sharif University of Technology, Tehran, Iran
In this paper, we propose and investigate several crosstalk reduction techniques for hybrid quantum-classical densewavelength- division-multiplexing systems. The transmission of intense classical signals alongside weak quantum ones on the same fiber introduces some crosstalk noise, mainly due to Raman scattering and nonideal channel isolation, that may severely aect the performance of quantum key distribution systems. We examine the conventional methods of suppressing this crosstalk noise, and enhance them by proposing an appropriate channel allocation method that reduces the background crosstalk eectively. Another approach proposed in this paper is the usage of orthogonal frequency division multiplexing, which oers ecient spectral and temporal filtering features.
http://scientiairanica.sharif.edu/article_3999_4a59e5d8f1a22b7b835fa98bcadeb338.pdf
Quantum key distribution
orthogonal frequency division multiplexing
crosstalk reduction
wavelength assignment
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2908
2916
10.24200/sci.2016.4000
4000
Improved CT Image Reconstruction Through Partial Fourier Sampling
Hasan Abbasi
abbasi_hasan@ee.sharif.ir
1
Zahra Kavehvash
kavehvash@sharif.edu
2
Mahdi Shabany
mahdi@sharif.edu
3
Sharif University Of Technology
Sharif University Of Technology
Sharif University Of Technology
A novel CT imaging structure based on compressive sensing (CS) is proposed. The main goal is to mitigate the CT imaging time and thus x-ray radiation dosage without compromising the image quality. The utilized compressive sensing approach is based on radial Fourier sampling. Thanks to the intrinsic relation between captured radon samples in a CT imaging process and the radial Fourier samples, partial Fourier sampling could be implemented systematically. This systematic compressive sampling helps in better control of required conditions such as incoherence and sparsity to guarantee adequate image quality in comparison to previous CS based CT imaging structures. Simulation results prove the superior quality of the proposed approach (about 4% better PSNR), achieving the smallest CT scan time and the best image quality.
http://scientiairanica.sharif.edu/article_4000_624d10c1181c6396e57b3be0e334e364.pdf
Computerized Tomography
Compressive Sensing
Partial Fourier
Systematic Sampling
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2917
2927
10.24200/sci.2016.4001
4001
A Multi-Objective Framework for Enhancing the Reliability and Minimizing the Cost of PMU Deployment in Power Systems
Farrokh Aminifar
1
Amir Safdarian
safdarian@sharif.edu
2
Mahmud Fotuhi-Firuzabad
3
Mohammad Shahidehpour
ms@iit.edu
4
Sharif University of Technology
Wide-area monitoring, protection, and control (WAMPAC) is a key factor in the implementation of smart transmission grids. WAMPAC has a crucial role in detection and prevention of widespread events with an ultimate goal of improving the electricity service reliability. Several mathematical techniques were proposed for the optimal phasor measurement units (PMU) placement (OPP) problem which represents the first step toward the development of WAMPAC. These techniques consider either the solution to the network observability or realization of specific PMU applications. This paper proposes a multi-objective framework for OPP which emphasizes the reliability of power systems. The objective functions minimize the investment cost and maximize the system reliability. Since the objectives are in conflict, the non-dominated sorting genetic algorithm II approach is adopted as an intelligent state sampling tool to find non-dominated solutions (Pareto front). The final placement scheme among Pareto points is chosen by a Fuzzy decision making approach.
http://scientiairanica.sharif.edu/article_4001_13c502a3c8d60d6b3aea16d273207fe2.pdf
Multi-objective optimization
non-dominated sorting genetic algorithm II
phasor measurement unit
optimal PMU placement
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2928
2933
10.24200/sci.2016.4002
4002
New basis functions for wave equation
S. Khorasani
khorasani@sina.sharif.edu
1
School of Electrical Engineering, Sharif University of Technology, Tehran, Iran
The Dierential Transfer Matrix Method is extended to the complex plane, which allows dealing with singularities at turning points. The results for real-valued systems are simplied and a pair of basis functions are found. These bases are a bit less accurate than WKB solutions but much easier to work with because of their algebraic form. Furthermore, these bases exactly satisfy the initial conditions and may go over the turning points without the divergent behavior of WKB solutions. The ndings of this paper allow explicit evaluation of eigenvalues of conned modes with high precision, as demonstrated by few examples.
http://scientiairanica.sharif.edu/article_4002_eb21634144773a037be4a1161479e755.pdf
Physical optics
Quantum optics
Electromagnetic optics
Inhomogeneous optical medi
eng
Sharif University of Technology
Scientia Iranica
1026-3098
2345-3605
2016-12-01
23
6
2934
2943
10.24200/sci.2016.4003
4003
Robust control of LVAD based on the sub-regional modeling of the heart
S. Ravanshadi
1
M. Jahed
jahed@sharif.edu
2
School of Electrical Engineering, Sharif University of Technology, Tehran, Iran
School of Electrical Engineering, Sharif University of Technology, Tehran, Iran
Left Ventricular Assist Devices (LVAD) have received renewed interest as a bridge-to-transplantation as well as a bridge-to-recovery device. Ironically, reports of malfunction and complications have hindered the growth of this device. In particular, the main concern is LVAD's susceptibility to excessive backlash and suction as a result of ows that are either too low or high, respectively. This study utilizes a wellestablished physiological model of the cardiovascular system as a reliable platform to study a proposed adaptive robust controller for a rotary motor based LVAD which overcomes such shortcomings. Proposed controller performance is evaluated by comparing simulated natural heart model with LVAD assisted diseased heart in various states, extending from 60 to 130 beats per minute (bpm). Simulation results of the proposed LVAD controller show that for heart rate of 75 bpm, systolic and diastolic blood pressures are 112 18 mmHg and 7316 mmHg, respectively. Furthermore, for the light exercise condition of 130 bpm, systolic and diastolic blood pressures increase to 155 19 mmHg and 96 14 mmHg, respectively. These results closely match natural heart clinical measurements, conrming proposed LVAD model and its adaptive robust controller to be a possible solution to current issues confronting the LVAD drives.
http://scientiairanica.sharif.edu/article_4003_27fef0414ad1352d13953dad17341ab8.pdf
Ventricular assist device
Adaptive robust control
Distributed model
Cardiovascular system