OPTIMIZED FUZZY BASED POWER CONTROL STRATEGY IN COGNITIVE RADIO NETWORKS IN MULTI FADING PROPAGATION ENVIRONMENTS

Bejjenki, Praneeth Kumar, Goraya, Muneeb Ahmed, Moid, Syed Fovad

January 2013

In this thesis we have considered a cognitive radio network (CRN) with a pair of primary user (PU) and secondary user (SU) in spectrum sharing networks in path-loss and without path-loss propagation environments under identically distributed m-Nakagami fading channel. The thesis consists of three parts. In the first part we propose an optimized Takagi-Sugeno Fuzzy Inference System (FIS) based power control strategy in cognitive radio networks (CRN) in spectrum sharing network in without path-loss propagation environment. The second part proposes an optimized Takagi-Sugeno FIS based power control strategy in cognitive radio networks in spectrum sharing network in path-loss propagation environment. For without path-loss propagation environment the proposed FIS takes the interference channel gain ratio between SU transmitter (CUtx) and PU receiver (PUrx) and Signal to Noise Ratio (SNR) towards PU transmitter (PUtx) as antecedents and outputs the power scaling factor for SU. For path-loss propagation environment the proposed FIS takes the relative distance ratio between CUtx and PUrx and SNR towards PUtx as antecedents and outputs the power scaling factor for SU. The output power scaling factor is used to vary the transmit power of SU such that it does not degrade the quality of service (QoS) of PU link. The third part presents an implementation of orthogonal frequency division multiplexing (OFDM) transmission technique in CRN. The OFDM technique has intellectual attractive features like coping with the inter symbol interference (ISI), while providing increasing spectral efficiency and improved performance. This can be used in emergency conditions where transmission requires reliability and high data rate. The OFDM transmission technique is applied towards SU transmitter in CRN, which enables SU to utilize the spectrum efficiently under various fading environments. Spectrum sharing networks in with and without path-loss propagation environments and OFDM transmission were tested for bit error rate (BER) performance after fading effects from m-Nakagami fading channel. We conclude that by applying Takagi-Sugeno Fuzzy Inference System (FIS) based power control strategy we can improve the BER performance of PU when compared with no power control strategy and with other fuzzy based power control technique. OFDM transmission technique gives us better data rate and slightly improved BER in CRN hence making it suitable for use in emergency conditions. / mobile: 0735032048 (Muneeb Goraya)

Cognitive Radio Networks

Spectrum Sharing Networks

Power Control

Takagi-Sugeno Fuzzy Inference System

m-Nakagami fading channel

OFDM.

Μελέτη ενεργο-αποδοτικών σχημάτων ελέγχου της ισχύος μετάδοσης επιπέδουελέγχου πρόσβασης στο μέσο για ασύρματα ad hoc δίκτυα

Γκάμας, Βασίλειος

20 September 2007

Το ζήτημα της κατανάλωσης ενέργειας σε ασύρματα ad hoc δίκτυα αποτελεί ένα ερευνητικό πεδίο το οποίο έχει λάβει ιδιαίτερη προσοχή τα τελευταία χρόνια. Οι σταθμοί σε ένα ασύρματο ad hoc δίκτυο λειτουργούν επί το πλείστον με μπαταρίες με αποτέλεσμα η εξοικονόμηση ενέργειας στο δίκτυο να αποτελεί πρώτιστο στόχο για την βιωσιμότητα των σταθμών του δικτύου και την αξιόπιστη παραλαβή των πακέτων δεδομένων από τους παραλήπτες τους. Μέχρι σήμερα, έχουν αναπτυχθεί διάφορα ενεργό-αποδοτικά πρωτόκολλα τα οποία μπορούν να υιοθετηθούν σε ένα ασύρματο ad hoc δίκτυo. Τα πρωτόκολλα αυτά λειτουργούν σε διαφορετικό επίπεδο το καθένα (ελέγχου πρόσβασης στο μέσο, δικτύου, υψηλότερα). Η παρούσα εργασία συντάχθηκε με σκοπό την μελέτη αυτών των ενεργό-αποδοτικών πρωτοκόλλων που μπορούν να υιοθετηθούν σε ασύρματα ad hoc δίκτυα, την καταγραφή των ιδιαίτερων χαρακτηριστικών κάθε πρωτοκόλλου καθώς και την ανάπτυξη ενός νέου πρωτοκόλλου ελέγχου της ισχύος μετάδοσης σε ασύρματα ad hoc δίκτυα με κύριο στόχο την περαιτέρω μείωση της κατανάλωσης ενέργειας στο δίκτυο με παράλληλη αύξηση του throughput του δικτύου. Συγκεκριμένα, στην παρούσα μελέτη, αναλύονται και παρουσιάζονται τα ακόλουθα ζητήματα. Στο Κεφάλαιο 1 παρουσιάζονται οι στόχοι της παρούσας εργασίας καθώς και η συνεισφορά της στο ζήτημα της κατανάλωσης ενέργειας στα ασύρματα ad hoc δίκτυα. Στο Κεφάλαιο 2 αρχικά πραγματοποιείται μία εισαγωγή στην αρχιτεκτονική των ασυρμάτων ad hoc δικτύων και ακολούθως παρουσιάζονται οι διάφορες κατηγορίες των ασυρμάτων ad hoc δικτύων, δίνοντας ιδιαίτερη έμφαση στην 802.11 τεχνολογία και πρωτόκολλα. Στο Κεφάλαιο 3 παρουσιάζονται υπάρχοντα ενεργό-αποδοτικά πρωτόκολλα τα οποία μπορούν να χρησιμοποιηθούν σε ασύρματα ad hoc δίκτυα. Τα πρωτόκολλα αυτά παρουσιάζονται ταξινομημένα ανάλογα με το επίπεδο στο οποίο το καθένα λειτουργεί (επίπεδο ελέγχου πρόσβασης στο μέσο, επίπεδο δικτύου, υψηλότερα επίπεδα). Στο Κεφάλαιο 4 περιγράφεται το προτεινόμενο MAC πρωτόκολλο ελέγχου της ισχύος μετάδοσης το οποίο μπορεί να χρησιμοποιηθεί σε ασύρματα ad hoc δίκτυα. Παρουσιάζεται η λειτουργία του πρωτοκόλλου, περιγράφοντας το χαρακτηριστικό της αργής εκκίνησης που το προτεινόμενο πρωτόκολλο υιοθετεί για την μετάδοση των RTS πλαισίων, καθώς και τον CTS μηχανισμό που χρησιμοποιείται. Στο τέλος του κεφαλαίου, πραγματοποιείται μια σύγκριση της λειτουργίας του προτεινόμενου ενεργό-αποδοτικού πρωτοκόλλου με υπάρχοντα πρωτόκολλα MAC επιπέδου που παρουσιάστηκαν στο Κεφάλαιο 3. Στο Κεφάλαιο 5 πραγματοποιείται αξιολόγηση της απόδοσης του προτεινόμενου πρωτοκόλλου. Η αξιολόγηση της απόδοσης του προτεινόμενου πρωτοκόλλου πραγματοποιείται μέσω της εκτέλεσης πειραμάτων με την βοήθεια του εξομοιωτή δικτύων network simulator 2. Η αξιολόγηση του προτεινόμενου πρωτοκόλλου πραγματοποιείται ως προς διάφορες παραμέτρους – κατανάλωση ενέργειας στο δίκτυο, διασπορά της καταναλόμενης ενέργειας, μέση καθυστέρηση παραλαβής των πακέτων, throughput του δικτύου, πλήθος συγκρούσεων RTS πλαισίων, λόγος ληφθέντων προς απεσταλμένα πακέτα – έχοντας ως βάση το πρόβλημα της εκκένωσης των πακέτων στο δίκτυο και για την περίπτωση δύο διαφορετικών προσεγγίσεων. Μία στην οποία κάθε σταθμός χρησιμοποιεί στατική ισχύ για τις μεταδόσεις του και μία στην οποία κάθε σταθμός ρυθμίζει την ισχύ μετάδοσής του στην ελάχιστη απαιτούμενη τιμή για την ορθή παραλαβή των πακέτων από τους παραλήπτες τους. Τέλος στο Κεφάλαιο 6 παρουσιάζονται τα συμπεράσματα που προκύπτουν από την παρούσα εργασία καθώς και διάφορα ανοιχτά ζητήματα προς περαιτέρω έρευνα. / Power consumption at wireless ad hoc networks has received last years much attention. Mobile stations in a wireless ad hoc network operate in the most cases with batteries, so power conservation at the network is a major objective for the viability of the mobile stations of the network and the reliable delivery of packets to their destinations. Till today, various power-aware protocols have been developed for wireless ad hoc networks. Each one of these protocols operates at different layer (medium access control, network, higher layers). The main objectives of this study are the review of the power-aware protocols that can be used at wireless ad hoc networks, the detection of the special characteristics of each protocol, and the development of a new power control MAC-layer protocol for wireless ad hoc networks. The main objective of this new protocol is the farther reduction of the power consumption in the network, with parallel increment at network throughput. More specifically speaking, in this study, the following points are represented and analyzed: in Chapter 1 the various objectives of this study are represented as the contribution of the study in point of power consumption at wireless ad hoc networks. In Chapter 2, initially an introduction at the architecture of wireless ad hoc networks is performed, while afterwards the various categories of wireless ad hoc networks are represented, by emphasizing the 802.11 technology and protocols. In Chapter 3 various energy-aware protocols for wireless ad hoc networks are represented. These protocols are represented categorized by the layer at which every one operates (medium access control layer, network layer and higher layers). In Chapter 4 the proposed power control MAC protocol for mobile ad hoc networks is represented. The operation of the protocol is represented, by describing the slow start mechanism used for RTS frames transmissions, and the CTS mechanism used. At the end of Chapter 4, a comparison between the operation of the proposed power-aware protocol and previous MAC-layer power aware protocols is performed. In Chapter 5, the performance evaluation of the proposed protocol is performed. The performance evaluation of the proposed protocol was done via execution of experiments with network simulator 2. The performance parameters that were measured are: the power consumption in the network, the variance of the consumed energy, the average delay for packets delivery, the network throughput, the number of RTS frames collisions and the received-to-sent packets ratio. The performance of the proposed protocol was evaluated in the setting of the evacuation problem and for two different approaches. One in which every node uses static power for its transmissions and one in which every node adjusts its transmission power at the minimum required value for coherent reception of the packets from the recipients. Finally in Chapter 6 are represented the results that are derived from this study and various open issues for further investigation.

Ασύρματο ad hoc δίκτυο

Έλεγχος ισχύος

IEEE 802.11

004.62

Wireless ad hoc network

Power control

IEEE 802.11

Collaborative beamforming for wireless sensor networks

Ahmed, Mohammed

Unknown Date

No description available.

WSNs

Multi-link collaborative beamforming

Spatial distribution

Power control

Node selection

Sidelobe control

Array processing

WSN lifetime

Random selection

CSI Feedback and Power Control in Wireless Networks

Karamad, Ehsan

10 January 2014

We investigate the effects of quantized channel state information (CSI) on the performance of resource allocation algorithms in wireless networks. The thesis starts with a brief overview of a specific type of quantizer, referred to as a conservative quantizer where we propose the optimality and sufficiency conditions as well as practical methods to find such quantizers. We apply this theory to the quantization of transmitter CSI in point-to-point Gaussian channels and transmission under short-term power constraints. Next, we show that in a multiple-node decode-and-forward (DF) cooperative network, the same structure for quantizer is close to op- timal for the sum-rate objective function. Based on a proposed upper bound on the rate loss in such scenarios, we also argue that the quantizer should assign uneven numbers of quantization bits to different links in the network. The simulation results show that given a target rate loss level, through quantization and bit allocation, there is, on average, 0.5−1 bits per link savings in CSI feedback requirements compared to the uniform and equal bit allocation approaches. Given the many benefits in non-uniform allocation of CSI rate in the network, we formulate a generalized bit allocation scheme which is extensible to arbitrary classes of network resource allocation problems. In the last part of this thesis, we focus on power control in an interference network and then, investigate the effects of CSI imperfections on the performance of power control algorithms. First, we propose an iterative power control algorithm based on a fixed-point iteration and prove its local convergence. Then, we show that for a centralized implementation of the power control algorithm, a uniform in dB (geometric) quantizer of channel power is efficient. Based on this choice of channel quantizer, we propose a bound on rate loss in terms of the resolution of the ii deployed quantizer, where a 3 dB in quantization error is shown to contribute to a maximum of 1 bit rate loss at each user. Similarly to the previous scenario, the upper bound suggests that an uneven assignment of numbers of quantization levels leads to smaller distortion. Based on this bound, we develop the corresponding bit allocation laws. We also investigate the effects of CSI errors on the performance of distributed power control algorithms and show that, compared to the centralized case, the distributed algorithm could lead to a further SINR loss of up to 3 dB for one or more transmitters. This error is due to the fact that because of CSI errors, the estimated interference level at each receiver is different from the induced interference wireless transmitters expect.

Wireless Communications

Interference Networks

Quantization

Channel State Feedback

Power Control

Convex Optimization

Cooperative Networks

Resource Allocation

0544

0984

CSI Feedback and Power Control in Wireless Networks

Karamad, Ehsan

10 January 2014

We investigate the effects of quantized channel state information (CSI) on the performance of resource allocation algorithms in wireless networks. The thesis starts with a brief overview of a specific type of quantizer, referred to as a conservative quantizer where we propose the optimality and sufficiency conditions as well as practical methods to find such quantizers. We apply this theory to the quantization of transmitter CSI in point-to-point Gaussian channels and transmission under short-term power constraints. Next, we show that in a multiple-node decode-and-forward (DF) cooperative network, the same structure for quantizer is close to op- timal for the sum-rate objective function. Based on a proposed upper bound on the rate loss in such scenarios, we also argue that the quantizer should assign uneven numbers of quantization bits to different links in the network. The simulation results show that given a target rate loss level, through quantization and bit allocation, there is, on average, 0.5−1 bits per link savings in CSI feedback requirements compared to the uniform and equal bit allocation approaches. Given the many benefits in non-uniform allocation of CSI rate in the network, we formulate a generalized bit allocation scheme which is extensible to arbitrary classes of network resource allocation problems. In the last part of this thesis, we focus on power control in an interference network and then, investigate the effects of CSI imperfections on the performance of power control algorithms. First, we propose an iterative power control algorithm based on a fixed-point iteration and prove its local convergence. Then, we show that for a centralized implementation of the power control algorithm, a uniform in dB (geometric) quantizer of channel power is efficient. Based on this choice of channel quantizer, we propose a bound on rate loss in terms of the resolution of the ii deployed quantizer, where a 3 dB in quantization error is shown to contribute to a maximum of 1 bit rate loss at each user. Similarly to the previous scenario, the upper bound suggests that an uneven assignment of numbers of quantization levels leads to smaller distortion. Based on this bound, we develop the corresponding bit allocation laws. We also investigate the effects of CSI errors on the performance of distributed power control algorithms and show that, compared to the centralized case, the distributed algorithm could lead to a further SINR loss of up to 3 dB for one or more transmitters. This error is due to the fact that because of CSI errors, the estimated interference level at each receiver is different from the induced interference wireless transmitters expect.

Wireless Communications

Interference Networks

Quantization

Channel State Feedback

Power Control

Convex Optimization

Cooperative Networks

Resource Allocation

0544

0984

Dynamic wireless access methods with applications to eHealth services

Phunchongharn, Phond

January 2009

For opportunistic spectrum access and spectrum sharing in cognitive radio networks, one key problem is how to develop wireless access schemes for secondary users so that harmful interference to primary users can be avoided and quality-of-service (QoS) of secondary users can be guaranteed. In this research, dynamic wireless access protocols for secondary users are designed and optimized for both infrastructure-based and ad-hoc wireless networks. Under the infrastructure-based model, the secondary users are connected through a controller (i.e., an access point). In particular, the problem of wireless access for eHealth applications is considered. In a single service cell, an innovative wireless access scheme, called electromagnetic interference (EMI)-aware prioritized wireless access, is proposed to address the issues of EMI to the medical devices and QoS differentiation for different eHealth applications. Afterwards, the resource management problem for multiple service cells, specifically, in multiple spatial reuse time-division multiple access (STDMA) networks is addressed. The problem is formulated as a dual objective optimization problem that maximizes the spectrum utilization of secondary users and minimizes their power consumption subject to the EMI constraints for active and passive medical devices and minimum throughput guarantee for secondary users. Joint scheduling and power control algorithms based on greedy approaches are proposed to solve the problem with much less computational complexity. In an ad-hoc wireless network, the robust transmission scheduling and power control problem for collision-free spectrum sharing between secondary and primary users in STDMA wireless networks is investigated. Traditionally, the problem only considers the average link gains; therefore, QoS violation can occur due to improper power allocation with respect to instantaneous channel gain realization. To overcome this problem, a robust power control problem is formulated. A column generation based algorithm is proposed to solve the problem by considering only the potential subset of variables when solving the problem. To increase the scalability, a novel distributed two-stage algorithm based on the distributed column generation method is then proposed to obtain the near-optimal solution of the robust transmission schedules for vertical spectrum sharing in an ad-hoc wireless network.

dynamic wireless access

interference control

robust optimization

scheduling

power control

eHealth applications

cognitive radio

Power control of single-stage PV inverter for distribution system volt-var optimization

Liu, Xiao

01 January 2013

The output power variability of intermittent renewable sources can cause significant fluctuations in distribution system voltages. A local linear controller that exploits the capability of a photovoltaic inverter to provide both real and reactive power is described. This controller substitutes reactive power for real power when fluctuations in the output of the photovoltaic source are experienced. In this way, the inverter can help mitigate distribution system voltage fluctuations. In order to provide real and reactive to the grid, a three-phase grid-connected single-stage photovoltaic system with maximum power point tracking and power control is described. A method of reducing the current harmonic caused by resonance of the LC filter and transformer is presented. The local linear controller is examined using an example distribution system, and it is found that the controller is effective at mitigating voltage violations. The photovoltaic control system is examined using three-phase single-stage PV inverter system. The power control and damping system show good performance and stability under rapid change of irradiance.

Distributed power generation

photovoltaic systems

power control

voltage control

virtual resistance damping.

Controls and Control Theory

Electrical and Electronics

Power and Energy

Dynamic wireless access methods with applications to eHealth services

Phunchongharn, Phond

January 2009

For opportunistic spectrum access and spectrum sharing in cognitive radio networks, one key problem is how to develop wireless access schemes for secondary users so that harmful interference to primary users can be avoided and quality-of-service (QoS) of secondary users can be guaranteed. In this research, dynamic wireless access protocols for secondary users are designed and optimized for both infrastructure-based and ad-hoc wireless networks. Under the infrastructure-based model, the secondary users are connected through a controller (i.e., an access point). In particular, the problem of wireless access for eHealth applications is considered. In a single service cell, an innovative wireless access scheme, called electromagnetic interference (EMI)-aware prioritized wireless access, is proposed to address the issues of EMI to the medical devices and QoS differentiation for different eHealth applications. Afterwards, the resource management problem for multiple service cells, specifically, in multiple spatial reuse time-division multiple access (STDMA) networks is addressed. The problem is formulated as a dual objective optimization problem that maximizes the spectrum utilization of secondary users and minimizes their power consumption subject to the EMI constraints for active and passive medical devices and minimum throughput guarantee for secondary users. Joint scheduling and power control algorithms based on greedy approaches are proposed to solve the problem with much less computational complexity. In an ad-hoc wireless network, the robust transmission scheduling and power control problem for collision-free spectrum sharing between secondary and primary users in STDMA wireless networks is investigated. Traditionally, the problem only considers the average link gains; therefore, QoS violation can occur due to improper power allocation with respect to instantaneous channel gain realization. To overcome this problem, a robust power control problem is formulated. A column generation based algorithm is proposed to solve the problem by considering only the potential subset of variables when solving the problem. To increase the scalability, a novel distributed two-stage algorithm based on the distributed column generation method is then proposed to obtain the near-optimal solution of the robust transmission schedules for vertical spectrum sharing in an ad-hoc wireless network.

dynamic wireless access

interference control

robust optimization

scheduling

power control

eHealth applications

cognitive radio

Power control for mobile radio systems using perceptual speech quality metrics

Rohani Mehdiabadi, Behrooz

January 2007

As the characteristics of mobile radio channels vary over time, transmit power must be controlled accordingly to ensure that the received signal level is within the receiver's sensitivity. As a consequence, modern mobile radio systems employ power control to regulate the received signal level such that it is neither less nor excessively larger than receiver sensitivity in order to maintain adequate service quality. In this context, speech quality measurement is an important aspect in the delivery of speech services as it will impact satisfaction of customers as well as the usage of precious system resources. A variety of techniques for speech quality measurement has been produced over the last few years as result of tireless research in the area of perceptual speech quality estimation. These are mainly based on psychoacoustic models of the human auditory systems. However, these techniques cannot be directly applied for real-time communication purposes as they typically require a copy of the transmitted and received speech signals for their operation. This thesis presents a novel technique of incorporating perceptual speech quality metrics with power control for mobile radio systems. The technique allows for standardized perceptual speech quality measurement algorithms to be used for in-service measurement of speech quality. The accuracy of the proposed Real-Time Perceptual Speech Quality Measurement (RTPSQM) technique with respect to measuring speech quality is first validated by extensive simulations. On this basis, RTPSQM is applied to power control in the Global System for Mobile (GSM) communication and the Universal Mobile Telecommunication System (UMTS). It is shown by simulations that the use of perceptual-based power control in GSM and UMTS outperforms conventional power control in terms of reducing the transmitter signal power required for providing adequate speech quality. This in turn facilitates the observed increase in system capacity and thus offers better utilization of available system resources. To enable an analytical performance assessment of perceptual speech quality metrics in power control, the mathematical frameworks for conventional and perceptual-based power control are derived. The derivations are performed for Code Division Multiple Access (CDMA) systems and kept as generic as possible. Numerical results are presented which could be used in a system design to readily find the Erlang capacity per cell for either of the considered power control algorithms.

Speech processing systems

Speech perception -- Mathematical models

Power control

Perceptual

Speech quality

Perceptual speech quality

IMPROVEMENTS IN INVERTER MODELING AND CONTROL

Liu, Xiao

01 January 2017

In this dissertation, the generalized averaging method models for inverters, reactive power control methods for photovoltaic inverters, and a noise immunity improvement for hybrid position observers for brushless dc motor drives are studied. Models of inverters and other converters based on averaging have been widely used in numerous simulation applications. Generalized averaging can be applied to model both average and switching behavior of converters while retaining the faster run times associated with average-value models. Herein, generalized average models for single- and three-phase pulse width modulation inverters are proposed. The modulation signal for the proposed model could be either a sinusoidal waveform without high order harmonics or a sinusoidal waveform with third-harmonic injection. And this generalized average models also can apply for modeling three-phase pulse width modulation inverters with varying modulation signal frequency in the reference frame. These models are based on a quasi-Fourier series representation of the switching functions that includes fundamental and switching frequency components as well as sideband components of the switching frequency. The proposed models are demonstrated both in simulation and experimentally and are found to accurately portray both the fundamental and the switching behavior of the inverter. In particular, the use of sideband components allows accurate representation of the variation in switching ripple magnitude that occurs in the steady state. The generalized average models are found to have simulation run times that are significantly faster than those associated with detailed models. Therefore, the proposed generalized average models are suitable for simulation applications in which both accuracy (including the switching behavior) and fast run times are required (e.g., long simulation times, systems with multiple converters, and repeated simulations). Variations in the output power of intermittent renewable sources can cause significant fluctuations of distribution system voltage magnitudes. Reactive power control methods that employ the reactive power capability of photovoltaic three-phase inverters to mitigate these fluctuations are proposed. These control methods cause the three-phase inverters to substitute reactive output power for real output power when fluctuations in the solar power are experienced, allowing the fluctuations to be controlled. Performance metrics for assessing the ability of these controllers to perform this mitigation are defined. The controllers are examined using the IEEE 123-bus feeder distribution system, and it is found that the controllers can effectively mitigate voltage magnitude fluctuations and that the appropriate choice of controller depends on the performance metrics of interest. Finally, a noise immunity improvement for hybrid position observers for brushless dc motor drives is proposed. A finite state machine is used to detect Hall-effect sensor transitions to determine if these transitions are true transitions or the result of momentary glitches. This filter causes a delay in the detection of the Hall-effect sensors that is compensated in the proposed observer. The proposed observer is compared in simulations with the original hybrid position observer under both non-noisy and noisy conditions for both constant and variable speed operation, and it has good performance even under high noise and variable speed conditions.

inverter

mathematical model

distributed power generation

reactive power control

brushless dc motor drive

observer

Electrical and Electronics

Power and Energy