Your search keyword '"Aryafar, Ehsan"' showing total 12 results

1. A deep learning framework for blockage mitigation and duration prediction in mmWave wireless networks

Author

Almutairi, Ahmed, Keshavarz-Haddad, Alireza, and Aryafar, Ehsan

Published

2024

2. An experimental study on beamforming architecture and full-duplex wireless across two operational outdoor massive MIMO networks

Author

Hosseini, Hadi, Almutairi, Ahmed, Hashir, Syed Muhammad, Aryafar, Ehsan, and Camp, Joseph

Published

2024

3. MmWave Tx-Rx Self-Interference Suppression through a High Impedance Surface Stacked EBG.

Author

Oladeinde, Adewale K., Aryafar, Ehsan, and Pejcinovic, Branimir

Subjects

ANTENNA design, TRANSMITTING antennas, RECEIVING antennas, ANTENNAS (Electronics), BAND gaps

Abstract

This paper proposes a full-duplex (FD) antenna design with passive self-interference (SI) suppression for the 28 GHz mmWave band. The reduction in SI is achieved through the design of a novel configuration of stacked Electromagnetic Band Gap structures (EBGs), which create a high impedance path to travelling electromagnetic waves between the transmit and receive antenna elements. The EBG is composed of stacked patches on layers 1 and 2 of a four-layer stack-up configuration. We present the design, optimization, and prototyping of unit antenna elements, stacked EBGs, and integration of stacked EBGs with antenna elements. We also evaluate the design through both HFSS (High Frequency Structure Simulator) and over-the-air measurements in an anechoic chamber. Through extensive evaluations, we show that (i) compared to an architecture that does not use EBGs, the proposed novel stacked EBG design provides an average of 25 dB of additional reduction in SI over 1 GHz of bandwidth, (ii) unit antenna element has over 1 GHz of bandwidth at −10 dB return loss, and (iii) HFSS simulations show close correlation with actual measurement results; however, measured results could still be several dB lower or higher than predicted simulation results. For example, the gap between simulated and measured antenna gains is less than 1 dB for 26–28 GHz and 28.5–30 GHz frequencies, but almost 3 dB for 28–28.5 GHz frequency band. [ABSTRACT FROM AUTHOR]

Published

2024

4. Spatially-Consistent Human Body Blockage Modeling: A State Generation Procedure.

Author

Gapeyenko, Margarita, Samuylov, Andrey, Gerasimenko, Mikhail, Moltchanov, Dmitri, Singh, Sarabjot, Akdeniz, Mustafa Riza, Aryafar, Ehsan, Andreev, Sergey, Himayat, Nageen, and Koucheryavy, Yevgeni

Subjects

HUMAN body, MOBILE computing

Abstract

Spatial correlation has been recognized by 3GPP as one of the key elements in millimeter-wave (mmWave) channel modeling. Correlated channel behavior is induced by macro objects, such as buildings, as well as by micro objects, including humans around the mmWave receivers. The 3GPP's three-dimensional (3D) spatially consistent channel model designed to capture these phenomena assumes a-priori knowledge of the correlation distance between the receivers. In this paper, we propose a novel spatially-consistent human body blockage state generation procedure, which extends the standardized 3D channel model by 3GPP to capture the correlation between the line-of-sight (LoS) links and the reflected cluster states affected by human body blockage. The proposed model is based on analytical expressions for the conditional link state probability, thus permitting the parametrization of the spatial field of receivers. It also does not require any a-priori information on the correlation distance as the latter is identified explicitly based on the environmental parameters. We compare the results for the proposed model with those obtained with the uncorrelated blockage model and conclude that in many special cases correlation manifests itself in quantitatively different propagation conditions experienced at the nearby receivers. [ABSTRACT FROM AUTHOR]

Published

2020

5. On the Temporal Effects of Mobile Blockers in Urban Millimeter-Wave Cellular Scenarios.

Author

Gapeyenko, Margarita, Samuylov, Andrey, Gerasimenko, Mikhail, Moltchanov, Dmitri, Singh, Sarabjot, Akdeniz, Mustafa Riza, Aryafar, Ehsan, Himayat, Nageen, Andreev, Sergey, and Koucheryavy, Yevgeni

Subjects

MILLIMETER wave propagation, MICROWAVE communication systems, MILLIMETER wave communication systems, CELL phone security measures, WIRELESS channels

Abstract

Millimeter-wave (mmWave) propagation is known to be severely affected by the blockage of the line-of-sight (LoS) path. In contrast to microwave systems, at shorter mmWave wavelengths such blockage can be caused by human bodies, where their mobility within environment makes wireless channel alternate between the blocked and non-blocked LoS states. Following the recent 3GPP requirements on modeling the dynamic blockage as well as the temporal consistency of the channel at mmWave frequencies, in this paper, a new model for predicting the state of a user in the presence of mobile blockers for representative 3GPP scenarios is developed: Urban micro cell street canyon and park/stadium/square. It is demonstrated that the blockage effects produce an alternating renewal process with exponentially distributed non-blocked intervals, and blocked durations that follow the general distribution. The following metrics are derived 1) the mean and the fraction of time spent in blocked/non-blocked state, 2) the residual blocked/non-blocked time, and 3) the time-dependent conditional probability of having blockage/no blockage at time t1 given that there was blockage/no blockage at time t0 . The latter is a function of the arrival rate (intensity), width, and height of moving blockers, distance to the mmWave access point (AP), as well as the heights of the AP and the user device. The proposed model can be used for system-level characterization of mmWave cellular communication systems. For example, the optimal height and the maximum coverage radius of the mmWave APs are derived, while satisfying the required mean data rate constraint. The system-level simulations corroborate that the use of the proposed method considerably reduces the modeling complexity. [ABSTRACT FROM PUBLISHER]

Published

2017

6. HetNets Selection by Clients: Convergence, Efficiency, and Practicality.

Author

Keshavarz-Haddad, Alireza, Aryafar, Ehsan, Wang, Michael, and Mung Chiang

Subjects

NONCOOPERATIVE games (Mathematics), NASH equilibrium, IEEE 802.11 (Standard), RADIO technology, IEEE 802.16 (Standard)

Abstract

We study the dynamics of network selection in heterogeneous wireless networks based on client-side control. Clients in such networks selfishly select the best radio access technology (RAT) that maximizes their own throughputs. We study two general classes of throughput models that capture the basic properties of random access (e.g., Wi-Fi) and scheduled access (e.g., WiMAX, LTE, and 3G) networks. Formulating the problem as a non-cooperative game, we study its existence of equilibria, convergence time, efficiency, and practicality. Our results reveal that: 1) single-class RAT selection games converge to Nash equilibria, while an improvement path can be repeated infinitely with a mixture of classes; 2) we provide tight bounds on the convergence time of these games; 3) we analyze the Pareto-efficiency of the Nash equilibria of these games, deriving the conditions under which Nash equilibria are Pareto-optimal, and quantifying the distance of equilibria with respect to the set of Pareto-dominant points when the conditions are not satisfied; and 4) with extensive measurement-driven simulations, we show that RAT selection games converge to Nash equilibria in a small number of steps, and are amenable to practical implementation. We also investigate the impact of noisy throughput estimates, and propose solutions to handle them. [ABSTRACT FROM PUBLISHER]

Published

2017

7. Rate Maximization in a UAV Based Full-Duplex Multi-User Communication Network Using Multi-Objective Optimization.

Author

Hashir, Syed Muhammad, Gupta, Sabyasachi, Megson, Gavin, Aryafar, Ehsan, and Camp, Joseph

Subjects

TELECOMMUNICATION systems, RESOURCE allocation, MULTICASTING (Computer networks)

Abstract

In this paper, we study an unmanned-aerial-vehicle (UAV) based full-duplex (FD) multi-user communication network, where a UAV is deployed as a multiple-input–multiple-output (MIMO) FD base station (BS) to serve multiple FD users on the ground. We propose a multi-objective optimization framework which considers two desirable objective functions, namely sum uplink (UL) rate maximization and sum downlink (DL) rate maximization while providing quality-of-service to all the users in the communication network. A novel resource allocation multi-objective-optimization-problem (MOOP) is designed which optimizes the downlink beamformer, the beamwidth angle, and the 3D position of the UAV, and also the UL power of the FD users. The formulated MOOP is a non-convex problem which is generally intractable. To handle the MOOP, a weighted Tchebycheff method is proposed, which converts the problem to the single-objective-optimization-problem (SOOP). Further, an alternative optimization approach is used, where SOOP is converted in to multiple sub-problems and optimization variables are operated alternatively. The numerical results show a trade-off region between sum UL and sum DL rate, and also validate that the considered FD system provides substantial improvement over traditional HD systems. [ABSTRACT FROM AUTHOR]

Published

2022

8. ADAM: An Adaptive Beamforming System for Multicasting in Wireless LANs.

Author

Aryafar, Ehsan, Khojastepour, Mohammad Ali, Sundaresan, Karthik, Rangarajan, Sampath, and Knightly, Edward

Subjects

ADAPTIVE computing systems, BEAMFORMING, MULTICASTING (Computer networks), WIRELESS communications, LOCAL area networks, FIELD programmable gate arrays, SIGNAL processing

Abstract

We present the design and implementation of ADAM, the first adaptive beamforming-based multicast system and experimental framework for indoor wireless environments. ADAM addresses the joint problem of adaptive beamformer design at the PHY layer and client scheduling at the MAC layer by proposing efficient algorithms that are amenable to practical implementation. ADAM is implemented on a field programmable gate array (FPGA) platform, and its performance is compared against that of omnidirectional and switched beamforming based multicast. Our experimental results reveal that: 1) switched multicast beamforming has limited gains in indoor multipath environments, whose deficiencies can be effectively overcome by ADAM to yield an average gain of threefold; 2) the higher the dynamic range of the discrete transmission rates employed by the MAC hardware, the higher the gains in ADAM's performance, yielding up to ninefold improvement over omni with the 802.11 rate table; and 3) finally, ADAM's performance is susceptible to channel variations due to user mobility and infrequent channel information feedback. However, we show that training ADAM's signal-to-noise ratio (SNR)-rate mapping to incorporate feedback rate and coherence time significantly increases its robustness to channel dynamics. [ABSTRACT FROM AUTHOR]

Published

2013

9. Synchronized CSMA Contention: Model, Implementation, and Evaluation.

Author

Aryafar, Ehsan, Salonidis, Theodoros, Shi, Jingpu, and Knightly, Edward

Subjects

CARRIER sense multiple access, COMPUTER network protocols, WIRELESS communications, IEEE 802.11 (Standard), FIELD programmable gate arrays, SPREAD spectrum communications, SYNCHRONIZATION

Abstract

A class of carrier sense multiple access (CSMA) protocols used in a broad range of wireless applications uses synchronized contention where nodes periodically contend at intervals of fixed duration. While several models exist for asynchronous CSMA contention used in protocols like IEEE 802.11 MAC, no model exists for synchronized CSMA contention that also incorporates realistic factors like clock drifts. In this paper, we introduce a model that quantifies the interplay of clock drifts with contention window size, control packet size, and carrier sense regulated by usage of guard time. Using a field programmable gate array (FPGA)-based MAC protocol implementation and controlled experiments on a wireless testbed, we evaluate the model predictions on the isolated and combined impact of these key performance factors to per-flow throughput and fairness properties in both single-hop and multihop networks. Our model and experimental evaluation reveal conditions on protocol parameters under which the throughput of certain flows can exponentially decrease; while at the same time, it enables solutions that can offset such problems in a predictable manner. [ABSTRACT FROM AUTHOR]

Published

2013

10. Coupled 802.11 Flows in Urban Channels: Model and Experimental Evaluation.

Author

Camp, Joseph, Aryafar, Ehsan, and Knightly, Edward

Subjects

INTERFERENCE channels (Telecommunications), MATHEMATICAL models, WIRELESS sensor networks, PROBABILITY theory, SIGNAL-to-noise ratio, TRANSMITTERS (Communication), INFORMATION asymmetry, AD hoc computer networks, COMPUTER network protocols

Abstract

Contending flows in multihop 802.11 wireless networks compete with two fundamental asymmetries: 1) channel asymmetry, in which one flow has a stronger signal, potentially yielding physical layer capture; and 2) topological asymmetry, in which one flow has increased channel state information, potentially yielding an advantage in winning access to the channel. Prior work has considered these asymmetries independently with a highly simplified view of the other. However, in this paper, we perform thousands of measurements on coupled flows in urban environments and build a simple yet accurate model that jointly considers information and channel asymmetries. We show that if these two asymmetries are not considered jointly, throughput predictions of even two coupled flows are vastly distorted from reality when traffic characteristics are only slightly altered (e.g., changes to modulation rate, packet size, or access mechanism). These performance modes are sensitive not only to small changes in system properties, but also small-scale link fluctuations that are common in an urban mesh network. We analyze all possible capture relationships for two-flow subtopologies and show that capture of the reverse traffic can allow a previously starving flow to compete fairly. Finally, we show how to extend and apply the model in domains such as modulation rate adaptation and understanding the interaction of control and data traffic. [ABSTRACT FROM AUTHOR]

Published

2012

11. An Experiment-Based Comparison between Fully Digital and Hybrid Beamforming Radio Architectures for Many-Antenna Full-Duplex Wireless Communication.

Author

Megson, Gavin, Gupta, Sabyasachi, Hashir, Syed Muhammad, Aryafar, Ehsan, and Camp, Joseph

Subjects

DIGITAL communications, WIRELESS communications, BEAMFORMING, WIRELESS channels, RADIO technology, KEY performance indicators (Management)

Abstract

Full-duplex (FD) communication in many-antenna base stations (BSs) is hampered by self-interference (SI). This is because a FD node's transmitting signal generates significant interference to its own receiver. Recent works have shown that it is possible to reduce/eliminate this SI in fully digital many-antenna systems, e.g., through transmit beamforming by using some spatial degrees of freedom to reduce SI instead of increasing the beamforming gain. On a parallel front, hybrid beamforming has recently emerged as a radio architecture that uses multiple antennas per FR chain. This can significantly reduce the cost of the end device (e.g., BS) but may also reduce the capacity or SI reduction gains of a fully digital radio system. This is because a fully digital radio architecture can change both the amplitude and phase of the wireless signal and send different data streams from each antenna element. Our goal in this paper is to quantify the performance gap between these two radio architectures in terms of SI cancellation and system capacity, particularly in multi-user MIMO setups. To do so, we experimentally compare the performance of a state-of-the-art fully digital many antenna FD solution to a hybrid beamforming architecture and compare the corresponding performance metrics leveraging a fully programmable many-antenna testbed and collecting over-the-air wireless channel data. We show that SI cancellation through beam design on a hybrid beamforming radio architecture can achieve capacity within 16% of that of a fully digital architecture. The performance gap further shrinks with a higher number of quantization bits in the hybrid beamforming system. [ABSTRACT FROM AUTHOR]

Published

2022

12. SAMU: design and implementation of frequency selectivity-aware multi-user MIMO for WLANs.

Author

Du, Yongjiu, Shi, Yan, Aryafar, Ehsan, Cui, Pengfei, Camp, Joseph, and Chiang, Mung

Subjects

TELECOMMUNICATION systems, DATA transmission systems, WIRELESS sensor networks, BANDWIDTHS, MIMO systems

Abstract

The traffic demand of wireless networks is expected to increase 1000-fold over the next decade. In anticipation of such increasing data demand for dense networks with a large number of stations, IEEE 802.11ax has introduced key technologies for capacity improvement including Orthogonal Frequency-Division Multiple Access (OFDMA), multi-user multi-input multi-output (MU-MIMO), and greater bandwidth. However, IEEE 802.11ax has yet to fully define a specific scheduling framework, on which the throughput improvement of networks significantly depends. Even within a 20 MHz of bandwidth, users experience heterogeneous channel orthogonality characteristics across sub-carriers, which prevents access points (APs) from achieving the ideal multi-user gain. Moreover, frequency selectivity increases as bandwidth scales and correspondingly severely deteriorates multi-user MIMO performance. In this work, we develop a novel channel adaptation scheme, named selectivity-aware multi-user MIMO (SAMU), to combat the issue of frequency selectivity and support coexistence among users in the network by jointly assigning subsets of sub-carriers to selected users and implementing downlink MU-MIMO. To do so, we first investigate the channel characteristics of an indoor environment. We then consider the frequency selectivity of current and emerging WiFi channel bandwidths to optimize multi-user MIMO by dividing the occupied sub-carrier resources into equally sized sub-channels according to the level of frequency selectivity. In our design, each sub-channel is allocated according to the largest bandwidth that can be considered frequency-flat, and an optimal subset of users is chosen to serve in each sub-channel according to spatial orthogonality. As a result, we support more simultaneous users than current 802.11 designs and achieve a significant performance improvement for all users in the network. Additionally, we propose a selectivity-aware high efficiency (SA-HE) mode, which is based on and fully backward compatible with the existing IEEE 802.11ax standard. Finally, over emulated and real indoor channels, we show that SAMU can achieve as much as 84.8% throughput improvement compared to existing multi-user MIMO schemes in IEEE 802.11ax. [ABSTRACT FROM AUTHOR]

Published

2018