Dr Azhar Iqbal

Research Fellow (A) (with PhD)

School of Computer and Mathematical Sciences

Faculty of Sciences, Engineering and Technology

Eligible to supervise Masters and PhD - email supervisor to discuss availability.

My Research
Career
Publications
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My research spans four domains: quantum game theory, game theory applications, geometric algebra applications, and mathematical modelling.

Quantum Game Theory: My primary research focus lies in the emergent field of quantum game theory, a novel interdisciplinary pursuit that extends the principles of classical game theory into the enigmatic world of quantum mechanics. This pioneering discipline is currently encompassed within the broader quantum information and computation research, where the implications of quantum mechanics are probed and applied to game theory, thereby opening new vistas in its analytical prowess.

Quantum game theory investigates the dynamics of strategic decision-making among rational agents, who possess quantum resources like quantum superposition and entanglement. The objective is to blend the principles of quantum mechanics into conventional game theory scenarios, shedding light on the potential of quantum technology to fundamentally transform our understanding of strategic interactions and decision-making processes.

In this novel realm, a quantum game can be described as strategic interaction among rational agents or 'players', who manipulate a quantum system. Several real-world implementations of quantum games employ local unitary transformations and quantum measurements to encapsulate the strategic manoeuvres and decision-making processes among players.

The payoffs or rewards for each player in a quantum game are shaped by the strategic choices of all participating players and are ultimately derived from the outcomes of quantum measurements. Consequently, the quantum state of the system is impacted by the collective decisions of the players, triggering a complex web of probabilities that dictate each player's payoff. By dissecting these probabilities and the strategic decisions leading to them, quantum game theory can illuminate the intricacies of strategic decision-making in a quantum context. This, in turn, could enable unprecedented applications of quantum technology across various disciplines.

The genesis of quantum games can be traced back to 1999 when David Meyer presented ground-breaking research [1 ,2 ,3 ] illustrating that the quantum algorithm for an oracle problem could be interpreted as a quantum strategy for a player in a two-player zero-sum game. Here, the other player adheres to classical strategy. Meyer's seminal contribution laid the groundwork for quantum game theory, forging a crucial link between quantum computing and game theory that has facilitated continued exploration of quantum technology within the landscape of strategic decision-making.

Soon after Meyer's pioneering work, Eisert, Wilkens, and Lewenstein [4 ,5 ] extended his findings by formulating a quantized interpretation of the famous Prisoners' Dilemma game. This quintessential game theory scenario involves two players who face the strategic dilemma of either cooperating or defecting, with their rewards contingent on the other player's decision. Through their investigation, Eisert, Wilkens, and Lewenstein substantiated the capacity of quantum technology to augment strategic decision-making, underscoring the compelling potential of quantum game theory within the broader domain of quantum information and computation research.

In essence, the capacity to construe quantum algorithms as strategic contests between quantum and classical players has led to the incorporation of game theory into the set of mathematical tools leveraged in the quest to expand the roster of viable quantum algorithms. By assimilating insights from game theory into the design of new quantum algorithms, researchers can acquire a more profound understanding of the intricate relationship between strategic decision-making and quantum mechanics. This, in turn, is instrumental in propelling the ongoing progression of quantum information and computation research.

My scholarly contributions in this domain encompass:

The concept of Evolutionarily Stable Strategy (ESS), first introduced by mathematical biologists in the 1970s [6 ,7 ], provides a model for an evolving population under evolutionary pressures. Widely recognized as the cornerstone of evolutionary game theory's stability solution, an ESS mathematically refines the set of symmetric Nash equilibria. My work in this area [8 ,9 ,10 ,11 ,12 ,13 ] delves into the destiny of an ESS when interactions among players within a population, engaged in pairwise symmetric games under evolutionary pressures, adopt quantum mechanics. My research has demonstrated that when pairwise games take on a quantum mechanical nature, quantum entanglement can facilitate the emergence of new Nash equilibria and concurrently influence the future of Nash equilibrium refinements. The manifestation of entanglement can significantly alter the evolution of strategies within a population, indicating potential quantum mechanical foundations for the emergence of self-organization and complexity in molecular-level interactions. A comprehensive review of this topic has been published as a chapter in the book “Quantum Aspects of Life” by the Imperial College Press [14 ];
Investigation into the fate of well-established game-theoretic solution concepts within a quantum game has been a focus of my research. This includes exploration of concepts such as "Social Optimality" [15 ], "Value of Coalition" [16 ], "Backwards-Induction Outcome" [17 ], and "Sub-Game Perfect Outcome" [18 ] within the quantum domain;
In-depth study of the Einstein-Podolsky-Rosen (EPR) framework for executing quantum games [19 ,20 ], which facilitates the identification of the genuinely quantum components of a quantum game;
Development of innovative strategies for creating quantum games, including schemes for quantizing games derived from the concept of non-factorizable joint probabilities [21 ] and from a system of Bell's inequalities [22 ];
My recent scholarly pursuits encompass: The introduction of a novel quantization scheme [40 ] wherein each player's quantum strategy is implemented through directional choices across three dimensions. This methodology provides an innovative, geometric, and intuitive means of representing quantum strategies. The formulation of an inventive scheme [41 ] to derive the quantum version of a classical game, grounded in Fine's theorem from the early 1980s. Utilizing Positive Operator-Valued Measures (POVMs), we ascertain the quantum states that rectify inherent paradoxes in classical games;
Study of quantum games that are played on networks [23 ]. This research explores the impact of quantum strategies on player behaviour in network games, where player interactions are modelled via network topology. Our findings reveal that quantum correlations can significantly influence the equilibrium strategies and outcomes of games that are played on networks;
My work also extends to quantum Bayesian games [24 , 25 ], which possess a more intricate underlying probability structure and offer a rich backdrop to examine the role of quantum probabilities. These papers open a new pathway for applying quantum games to analyse decision-making and information exchange in games characterized by incomplete information;
Investigating [26 ] the application of quantum games to improve our understanding and portrayal of concept combinations in human cognition.

Game Theory Applications: My notable contributions in this field encompass:

The development of an extension to Selten's widely recognized ransom kidnapping game model [27 ];
An insightful review article [40 ] discussing the applications of game theory in the domain of network and cybersecurity.

Geometric Algebra Applications: Geometric Algebra (GA) marries the algebraic structure of Clifford’s algebra with a discernible geometric interpretation, thus enhancing geometric intuition with the precision of an algebraic system. My work on applying GA includes:

A GA-driven analysis of Meyer's quantum penny-flip game [28 ];
A study of two-player and three-player quantum games in an EPR-type setup, leveraging GA [29 , 30 ];
Exploration of special relativity through the mathematical formalism of GA [31 ];
An investigation of N-player quantum games within an EPR context [32 ];
Advancement of an enhanced formalism for quantum computation grounded in GA and its implementation in Grover's search algorithm [33 ];
An investigation into the advantages of GA formalism for engineers [34 ];
A study of the functions of multivector variables within GA [35 ];
Examination of time as a geometric property within the GA-conceived perception of space [36 ];
Showing how the structure of Minkowski's four dimensional spacetime continuum emerges as a natural property of physical three-dimensional space, if it is modeled with GA [43].

Mathematical Modelling: This field involves the use of mathematical concepts and language for system descriptions. My contributions include:

Formulation of mathematical models for memristive devices, and their applications in circuits and system simulations [37 ,38 ,39 ]. Memristors, a class of passive circuit element, can store information and maintain a relationship between the time integrals of current and voltage across a two-terminal element;
Supervision of a research project concentrating on the mathematical modeling of the COVID-19 outbreak in Bahrain [41 ,42].

To view my research impact indicators, please visit the following links: ORCID , Web of Science , Google Scholar , Scopus , Loop , ResearchGate , and Academia .

Appointments

Date Position Institution name
2007 - ongoing Researcher University of Adelaide
2006 - 2007 JSPS Postdoctoral Research Fellow Kochi University of Technology
Language Competencies

Language Competency
English Can read, write, speak, understand spoken and peer review
Urdu Can read, write, speak, understand spoken and peer review
Education

Date Institution name Country Title
2002 - 2006 University of Hull United Kingdom PhD in Applied Mathematics
1992 - 1995 University of Sheffield United Kingdom BSc (Honours) in Physics
Research Interests

Decision Theory Mathematical Aspects of Quantum Mathematical Physics Operations Research Optimisation Quantum Information Theory Quantum Information, Computation and Communication Quantum Mechanics

Date	Position	Institution name
2007 - ongoing	Researcher	University of Adelaide
2006 - 2007	JSPS Postdoctoral Research Fellow	Kochi University of Technology

Language	Competency
English	Can read, write, speak, understand spoken and peer review
Urdu	Can read, write, speak, understand spoken and peer review

Date	Institution name	Country	Title
2002 - 2006	University of Hull	United Kingdom	PhD in Applied Mathematics
1992 - 1995	University of Sheffield	United Kingdom	BSc (Honours) in Physics

Journals

Year	Citation
2023	Chappell, J. M., Hartnett, J. G., Iannella, N., Iqbal, A., Berkahn, D. L., & Abbott, D. (2023). A new derivation of the Minkowski metric. Journal of Physics Communications, 7(6), 065001. DOI
2022	Iqbal, A., & Abbott, D. (2022). Two-player quantum games: When player strategies are via directional choices. Quantum Information Processing, 21(6), 26 pages. DOI Scopus2 WoS1
2021	AlSayegh, M. A. K., & Iqbal, A. (2021). The impact of the precautionary measures taken in the kingdom of Bahrain to contain the outbreak of COVID-19. Arab Journal of Basic and Applied Sciences, 28(1), 195-203. DOI Scopus4
2019	Iqbal, A., Gunn, L. J., Guo, M., Babar, M. A., & Abbott, D. (2019). Game theoretical modelling of network/cybersecurity. IEEE Access, 7, 154167-154179. DOI Scopus9 WoS9
2018	Iqbal, A., Chappell, J., & Abbott, D. (2018). The equivalence of Bell's inequality and the Nash inequality in a quantum game-theoretic setting. Physics Letters A, 382(40), 2908-2913. DOI Scopus5 WoS5
2018	Iqbal, A., & Abbott, D. (2018). A game theoretical perspective on the quantum probabilities associated with a GHZ state. Quantum Information Processing, 17(11), 313-1-313-13. DOI Scopus3 WoS3
2017	Iqbal, A., Masson, V., & Abbott, D. (2017). Kidnapping model: an extension of Selten’s game. Royal Society Open Science, 4(12), 171484-1-171484-10. DOI Scopus3 WoS4
2016	Zhou, S., Valchev, D. G., Dinovitser, A., Chappell, J. M., Iqbal, A., Ng, B. W. -H., . . . Abbott, D. (2016). Terahertz signal classification based on geometric algebra. IEEE Transactions on Terahertz Science and Technology, 6(6), 793-802. DOI Scopus13 WoS13
2016	Chappell, J. M., Hartnett, J. G., Iannella, N., Iqbal, A., & Abbott, D. (2016). Time as a geometric property of space. Frontiers in Physics, 4(NOV), 44. DOI Scopus1 WoS2
2016	Chappell, J., Iqbal, A., Hartnett, J., & Abbott, D. (2016). The vector algebra war: a historical perspective. IEEE Access, 4, 1997-2004. DOI Scopus16 WoS15
2016	Iqbal, A., Chappell, J., & Abbott, D. (2016). On the equivalence between non-factorizable mixed-strategy classical games and quantum games. Royal Society Open Science, 3(1), 1-11. DOI Scopus15 WoS15 Europe PMC4
2015	Chappell, J., Iqbal, A., Gunn, L., & Abbott, D. (2015). Functions of multivector variables. PLoS One, 10(3), e0116943-1-e0116943-21. DOI Scopus13 WoS31
2015	Iqbal, A., Chappell, J., & Abbott, D. (2015). Social optimality in quantum Bayesian games. Physica A: Statistical Mechanics and its Applications, 436, 798-805. DOI Scopus19 WoS17
2014	Chappell, J. M., Drake, S. P., Seidel, C. L., Gunn, L. J., Iqbal, A., Allison, A., & Abbott, D. (2014). Geometric algebra for electrical and electronic engineers. Proceedings of the IEEE, 102(9), 1340-1363. DOI Scopus43 WoS38
2014	Iqbal, A., Chappell, J. M., Li, Q., Pearce, C. E. M., & Abbott, D. (2014). A probabilistic approach to quantum Bayesian games of incomplete information. Quantum Information Processing, 13(2), 2783-2800. DOI Scopus21 WoS20
2013	Li, Q., Chen, M., Perc, M., Iqbal, A., & Abbott, D. (2013). Effects of adaptive degrees of trust on coevolution of quantum strategies on scale-free networks. Scientific Reports, 3, 1-7. DOI Scopus31 WoS29 Europe PMC7
2013	Li, Q., Iqbal, A., Perc, M., Chen, M., & Abbott, D. (2013). Coevolution of quantum and classical strategies on evolving random networks. PLoS One, 8(7), 1-10. DOI Scopus31 WoS24 Europe PMC8
2013	Chappell, J., Iqbal, A., Lohe, M., Von Smekal, L., & Abbott, D. (2013). An improved formalism for quantum computation based on geometric algebra - case study: Grover's search algorithm. Quantum Information Processing, 12(4), 1719-1735. DOI Scopus4 WoS4
2012	Eshraghian, K., Kavehei, O., Cho, K. R., Chappell, J., Iqbal, A., Al-Sarawi, S., & Abbott, D. (2012). Memristive device fundamentals and modeling: applications to circuits and systems simulation. Proceedings of the IEEE, 100(6), 1991-2007. DOI Scopus105 WoS88
2012	Chappell, J., Iqbal, A., & Abbott, D. (2012). N-player quantum games in an EPR setting. PLoS One, 7(5), 1-9. DOI Scopus19 WoS16 Europe PMC3
2012	Li, Q., Iqbal, A., Chen, M., & Abbott, D. (2012). Quantum strategies win in a defector-dominated population. Physica A, 391(11), 3316-3322. DOI Scopus27 WoS26
2012	Chappell, J., Iqbal, A., & Abbott, D. (2012). Analysis of two-player quantum games in an EPR setting using Clifford's geometric algebra. PLoS One, 7(1), e29015-1-e29015-8. DOI Scopus12 WoS12 Europe PMC4
2012	Chappell, J., Chappell, M., Iqbal, A., & Abbott, D. (2012). The gravity field of a cube. Physics International, 3(2), 50-57. DOI
2012	Chappell, J., Iqbal, A., Iannella, N., & Abbott, D. (2012). Revisiting special relativity: a natural algebraic alternative to Minkowski spacetime. PLoS One, 7(12), 1-10. DOI Scopus8 WoS6 Europe PMC1
2012	Li, Q., Iqbal, A., Chen, M., & Abbott, D. (2012). Evolution of quantum strategies on a small-world network. European Physical Journal B, 85(11), 1-9. DOI Scopus6 WoS6
2012	Li, Q., Iqbal, A., Chen, M., & Abbott, D. (2012). Evolution of quantum and classical strategies on networks by group interactions. New Journal of Physics, 14(10), 1-13. DOI Scopus16 WoS14
2011	Chappell, J., Iqbal, A., & Abbott, D. (2011). Analyzing three-player quantum games in an EPR type setup. PLoS One, 6(7), 1-11. DOI Scopus17 WoS18 Europe PMC8
2011	Chappell, J., Lohe, M., Von Smekal, L., Iqbal, A., & Abbott, D. (2011). A precise error bound for quantum phase estimation. PLoS One, 6(5), e19663-1-e19663-4. DOI Scopus5 WoS3
2010	Chappell, J., Iqbal, A., & Abbott, D. (2010). Constructing quantum games from symmetric non-factorizable joint probabilities. Physics Letters A, 374(40), 4104-4111. DOI Scopus12 WoS13
2010	Kavehei, O., Iqbal, A., Kim, Y., Eshraghian, K., Al-Sarawi, S., & Abbott, D. (2010). The fourth element: characteristics, modelling and electromagnetic theory of the memristor. Proceedings of the Royal Society of London Series A-Mathematical Physical and Engineering Sciences, 466(2120), 2175-2202. DOI Scopus159 WoS112
2010	Iqbal, A., & Abbott, D. (2010). Constructing quantum games from a system of Bell's inequalities. Physics Letters A, 374(31-32), 3155-3163. DOI Scopus21 WoS20
2009	Iqbal, A., & Abbott, D. (2009). Non-factorizable joint probabilities and evolutionarily stable strategies in the quantum prisoner's dilemma game. Physics Letters A, 373(30), 2537-2541. DOI Scopus11 WoS8
2009	Chappell, J., Iqbal, A., Lohe, M., & Von Smekal, L. (2009). An analysis of the quantum penny flip game using geometric algebra. Journal of the Physical Society of Japan, 78(54801), 1-4. DOI Scopus19 WoS18
2009	Iqbal, A., & Abbott, D. (2009). Quantum matching pennies game. Journal of the Physical Society of Japan, 78(1), 014803-1-014803-8. DOI Scopus22 WoS19
2008	Iqbal, A., Cheon, T., & Abbott, D. (2008). Probabilistic analysis of three-player symmetric quantum games played using the Einstein-Podolsky-Rosen-Bohm setting. Physics Letters A, 372(44), 6564-6577. DOI Scopus32 WoS30
2008	Cheon, T., & Iqbal, A. (2008). Bayesian Nash equilibria and Bell inequalities. Journal of the Physical Society of Japan, 77(2), 024801 (6 pages). DOI Scopus42 WoS39
2007	Iqbal, A., & Cheon, T. (2007). Constructing quantum games from nonfactorizable joint probabilities. Physical Review E. (Statistical, Nonlinear, and Soft Matter Physics), 76(6), 061122-1-061122-12. DOI Scopus26 WoS22 Europe PMC1
2005	Iqbal, A. (2005). Playing games with EPR-type experiments. Journal of Physics A: Mathematical and Theoretical (Print Edition), 38(43), 9551-9564. DOI Scopus15 WoS14
2004	Iqbal, A., & Toor, A. (2004). Stability of mixed Nash equilibria in symmetric quantum game. Communications in Theoretical Physics, 42(3), 335-338. DOI Scopus14 WoS12
2004	Iqbal, A., & Weigert, S. (2004). Quantum correlation games. Journal of Physics A: Mathematical and Theoretical (Print Edition), 37(22), 5873-5885. DOI Scopus32 WoS29
2004	Iqbal, A. (2004). Quantum correlations and Nash equilibria of a bi-matrix game. Journal of Physics A: Mathematical and Theoretical (Print Edition), 37(29), L353-L359. DOI Scopus8 WoS5
2003	Iqbal, A. (2003). Quantum games with a multi-slit electron diffraction set-up. Societa Italiana di Fisica Nuovo Cimento B: General Physics, Relativity Astronomy and Mathematical Physics and Methods, 118(5), 463-468. DOI Scopus1
2002	Iqbal, A., & Toor, A. H. (2002). Quantum mechanics gives stability to a Nash equilibrium. Physical Review A, 65(2), 022306-1-022306-5. DOI Scopus59 WoS51
2002	Iqbal, A., & Toor, A. H. (2002). Quantum cooperative games. Physics Letters A, 293(3-4), 103-108. DOI Scopus47 WoS44
2002	Iqbal, A., & Toor, A. H. (2002). Quantum repeated games. Physics Letters A, 300(6), 541-546. DOI Scopus31 WoS28
2002	Iqbal, A., & Toor, A. H. (2002). Darwinism in quantum systems?. Physics Letters A, 294(5-6), 261-270. DOI Scopus21 WoS18
2002	Iqbal, A., & Toor, A. H. (2002). Backwards-induction outcome in a quantum game. Physical Review A, 65(5), 052328-1-052328-8. DOI Scopus65 WoS63
2001	Iqbal, A., & Toor, A. H. (2001). Evolutionarily stable strategies in quantum games. Physics Letters A, 280(5-6), 249-256. DOI Scopus101 WoS88
2001	Iqbal, A., & Toor, A. H. (2001). Entanglement and dynamic stability of Nash equilibria in a symmetric quantum game. Physics Letters A, 286(4), 245-250. DOI Scopus25 WoS22

Book Chapters

Year	Citation
2008	Iqbal, A., & Cheon, T. (2008). Evolutionary stability in quantum games. In D. Abbott, P. Davies, & A. Pati (Eds.), Quantum Aspects of Life (pp. 251-288). London: Imperial College Press. DOI Scopus7

Conference Papers

Year	Citation
2021	AlSayegh, M. A. K., & Iqbal, A. (2021). The impact of the vaccination and booster shots in containing the COVID-19 epidemic in Bahrain: a game theory approach. In 2021 Third International Sustainability and Resilience Conference: Climate Change (SRC 2021) (pp. 1-6). Virtual online: IEEE. DOI
2016	Zhou, S. L., Valchev, D. G., Dinovitser, A., Chappell, J. M., Iqbal, A., Ng, B. W. -H., . . . Abbott, D. (2016). Dispersion-independent terahertz classification based on Geometric Algebra for substance detection. In Infrared, Millimeter, and Terahertz waves (IRMMW-THz), 2016 41st International Conference on Vol. 2016-November (pp. 1-2). online: IEEE. DOI Scopus1
2010	Bruza, P., Iqbal, A., & Kitto, K. (2010). The role of non-factorizability in determining "pseudo-classical" non-separability. In AAAI Fall Symposium - Technical Report Vol. FS-10-08 (pp. 26-31). Scopus4
2010	Bruza, P., Iqbal, A., & Kitto, K. (2010). The role of non-factorizability in determining ''Pseudo-classical' non-separability. In Proceedings of Quantum Informatics 2010 (pp. 1-6). www.aaai.org: AAAI.
2009	Kavehei, O., Kim, Y. S., Iqbal, A., Eshraghian, K., Al-Sarawi, S., & Abbott, D. (2009). The fourth element: Insights into the Memristor. In Proceedings of ICCCAS 2009 (pp. 921-927). USA: IEEE. DOI Scopus26 WoS27
2008	Iqbal, A., & Cheon, T. (2008). Constructing multi-player quantum games from non-factorizable joint probabilities - art. no. 68020A. In D. Abbott, T. Aste, M. Batchelor, R. Dewar, T. DiMatteo, & T. Guttmann (Eds.), COMPLEX SYSTEMS II Vol. 6802 (pp. A8020). Canberra, AUSTRALIA: SPIE-INT SOC OPTICAL ENGINEERING. WoS2
2007	Iqbal, A., & Cheon, T. (2007). Constructing multi-player quantum games from non-factorizable joint probabilities. In SPIE Microelectronics, MEMS, and Nanotechnology 2007 Proceedings Vol. 6802 (pp. 1-9). Sydney: SPIE. DOI Scopus8

Conference Items

Year	Citation
2017	32nd Annual Meeting and Pre-Conference Programs of the Society for Immunotherapy of Cancer (SITC 2017): Late-Breaking Abstracts (2017). Poster session presented at the meeting of Journal for ImmunoTherapy of Cancer. BMJ. DOI

Internet Publications

Year	Citation
2022	Iqbal, A. (2022). An Urdu translation of the Australian National Anthem.
2022	Iqbal, A. (2022). An Urdu translation of the Australian National Anthem.
2019	Iqbal, A., & Abbott, D. (2019). Quantum strategies and evolutionary stability (in Urdu). Eqbal Ahmad Centre for Public Education: https://eacpe.org/.
2019	Iqbal, A., Hoodbhoy, P., & Abbott, D. (2019). Can Quantum-Mechanical Description of Physical Reality Be Considered Complete? (An Urdu Translation). Eqbal Ahmad Centre for Public Education.
2016	Iqbal, A. (2016). Looking at World Events Through the Prism of Game Theory. SAGE International Australia.

Faculty of Engineering, Computer & Mathematical Sciences (ECMS) Interdisciplinary Research Grant Scheme 2016 (jointly with Prof Derek Abbott & Dr Virginie Masson) at the University of Adelaide, AU$ 30,000 (2016-2017)
Discovery Research Grant DP0771453 and Fellowship (Principal Investigator) from Australian Research Council (ARC) at University of Adelaide, AU$ 247,092 (2007-2011)
Research Grant P06330 and Fellowship (Principal Investigator) from Japan Society for the Promotion of Science (JSPS) at Kochi University of Technology, Japanese Yen 4,958,500 (2006-2007)
Fully funded PhD Research Scholarship from the University of Hull, UK, for overseas research students (2002-2005)
Fully funded Merit Scholarship from the Government of Pakistan for studying overseas at the University of Sheffield, UK (1992-1995)

Department of Mathematics, College of Science, University of Bahrain (UoB):

2^nd Semester 2020-2021:

Fluid Mechanics (Level 3)
Calculus II (Level 1)
Calculus & Analytical Geometry II (Level 1)
Calculus & Analytical Geometry III (Level 2)

1^st Semester 2020-2021:

Analytical Mechanics (Level 3)
Methods of Applied Mathematics (Level 3)
Calculus II (Level 1)

2^nd Semester 2019-2020:

Calculus II (Level 1)
Maths for Business Management (Level 1)
Calculus & Analytic Geometry III (Level 2)

School of Electrical & Electronic Engineering, University of Adelaide:

Avionic Sensors & Systems Combined (Level 4), 2014 Semester 2: Guest Lecturer
Communications/Principles of Communication Systems (Combined) (Level 4), 2012 Semester 1: Guest Lecturer
Communications/Principles of Communication Systems (Combined) (Level 4), 2011 Semester 1: Guest Lecturer

Department of Mathematics & Statistics, King Fahd University of Petroleum & Minerals (KFUPM):

Methods of Applied Mathematics (Level 3), Jan 2013 to May 2014, taught this course 4 times
Elements of Differential Equations (Level 2), Jan 2013 to May 2014, taught this course twice

School of Natural Sciences, National University of Sciences & Technology (NUST):

Mathematical Foundations of Quantum Mechanics (Level 4), July-Nov 2006

Riphah International University (RUI):

Engineering Electromagnetics (Level 2), Sep 2000-Sep 2001

Tutoring experience

School of Electrical & Electronic Engineering, University of Adelaide:

Vector Calculus & Electromagnetics (Level 2), 2022 Semester 2
Electronic Circuits (Level 2), 2022 Semester 1
Electronic Circuits (Level 2), 2018 Semester 1
Electronic Circuits (Level 2), 2017 Semester 1
Electronic Circuits (Level 2), 2016 Semester 1
Electronic Systems (Level 1), 2016 Semester 1

Maths Learning Centre (MLC), University of Adelaide:

Undergrad Maths courses (Various Levels), 2017 to 2019

Position: Research Fellow (A) (with PhD)
Phone: 83135589
Email: azhar.iqbal@adelaide.edu.au
Campus: North Terrace
Building: Ingkarni Wardli, floor Level Three
Org Unit: Electrical and Electronic Engineering

Dr Azhar Iqbal

Appointments

Language Competencies

Education

Research Interests

Journals

Book Chapters

Conference Papers

Conference Items

Internet Publications

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