Dr Mahmoud Efatmaneshnik

Research Associate
School of Engineering and Information Technology
  • ABOUT
  • PUBLICATIONS

Dr Mahmoud Efatmaneshnik a PhD in Complexity management of Design Process (2009), and a ME in manufacturing engineering (2005) both from UNSW. He has a BE in aerospace (1999) from Tehran Polytechnic university. Mahmoud is active member of INCOSE and holds a number of committee positions in Systems Engineering Society of Australia. He is author of over 70 book chapters, journal papers, and refereed conference papers. 

His resaerch interests are:

  • Systems Engineering
  • Systems modeling and analysis
  • Complexity modeling and complexity measures
  • Decision support system for design and engineering
  • Design decision analysis and Risk management
  • Capability modelling and acquisition model development

He currently has a number PhD projects in several general areas including:

Risk and Complexity Management in Systems Engineering

  1. Investigating Application of Possibility theory to Systems Engineering Risk Management

Complex systems are characterized by many future possibilities each with a tiny probability. The traditional risk analysis that considers probability versus impact might not be helpful when the number of futures is too many. This project aims at finding parallel risk management methods based on possibility theory rather than probability theory. This project is highly mathematical and is a suitable for a candidate with deep understanding of probability, fuzzy set and possibility theories.

  1. Investigation of Failure Propagation Mechanisms in Complex Systems

The aim of this project is to characterise failure propagation in various kinds of systems such as enterprises (human systems), software and hardware systems, mechanical systems and heterogeneous systems such as system of systems. The models are then used to characterise the fragility and robustness of these systems. The generated models are then put into the more general context of resilience engineering where various resilience engineering mechanisms are validated against characteristics of system responses to failure propagation.

  1. Probabilistic Systems Engineering Model: Synthesis and Validation

The aim of this project is to synthesize building blocks of a Probabilistic Systems Engineering Model and its validation. The model would be based on probabilistic success in execution of systems engineering task and resulting rework. Four basic systems engineering tasks are considered initially:

  1. Problem identification
  2. Solution Synthesis
  3. Integration
  4. Test

For each of these tasks will be characterized with a set of probability measures that will indicate the success or failure. Then these measures are applied to a network view the system. One major task in this project is the identification of an appropriate solver for the network such as Bayesian network, Petri Net, Generalized Networks or other models based random graph theory. The solver must be able to identify lead time, rework and quality of the constructed system.

Systems Architecture Optimisation

  1. System Architecture Evaluation and Optimization at Early Conceptual Design Stage

Defence systems acquisition is fraught with all sorts of financial, technical and political risks. The most effective way of mitigating risks associated with acquisition of complex systems is through identification of these risks as early as possible. This project’s aim is to facilitate optimal decision making for multi stakeholder system design.

This project sets to examine an architectural selection model based on minimal information at early stages of conceptual design. The system architecture, determined by integration and test plans is a key factor in management of the uncertainties associated with technology, processes and tests. This project will examine and categorise these uncertainties and will investigate ways of evaluating competing system architectures based on the identified risks, such as through estimation of the likely values and variances of project cost and time associated with each architecture.

  1. An Integrated Stakeholder Preference Modelling and Tradespace Evaluation Framework

This project’s aim is to facilitate optimal decision making for multi stakeholder system design. This study will investigation all available preference modelling methods and asses their utility for integration with Tradespace exploration techniques.

  1. Creating and Managing System Modularity: A Trade off and Optimality Analysis

Modularity as a system property has many benefits for different lifecycle stages of a system. This project is an investigation of a complete set of these benefits as well as a search for optimum formation of the modules for maximum benefit to all or some the identified benefits, at early design stages.

  1. Investigation of Methods and Methodologies for Systems Engineering of Non-functional Requirements

Systems Engineering methodology applies aptly to functional design of systems. However, for non-functional requirements, the current methodology does not have a lot to offer and there is a lack of concrete methodologies for non-functional systems engineering. Specific modularization of systems elements is a powerful tool for the design of the non-functional requirements into the systems. This project investigates ways that modularization can be integrated into the standard systems engineering process. It also may involve creation of a complete taxonomy for non-functional requirements and their ontology.

Human Systems Engineering

  1. Investigating Best Practices in Human-Systems Integration and Engineering Methodologies

This project aims at identifying current state of the art human systems integration techniques and creation of framework for an overarching or generalized human system integration framework that can be substantiated for different kinds of systems. Human systems integration practices are very domain specific for example healthcare, defence, aerospace etc. However, there is no agreed upon methodology that can be instantiated for any kind of systems. This project takes step back to the principles of human systems integration and based on those principles creates a methodology for human systems integration. The project will include an Investigation of the Role of Human Systems Integration in Engineering of Complex Systems

  1. Investigation of Competency Model Integration with Project Management

This project is part of a much larger vision to measure complexity of projects from subjective views for task and resource allocation purposes. Several competency models have been proposed and used in defence. The project aims at:

  1. Identifying usability of competency frameworks with task complexity measurement.
  2. Integration of competency frameworks with task complexity measure.
  3. Investigation of optimality and validity of system selection for minimum complexity given set of available resources and their competency models and set of problem space elements.

 

 

 

Books

Efatmaneshnik M; Reidsema CA, 2009, A comprehensive treatment of complex systems engineering design: Coping with complexity of products processes and organizations, LAP Lambert Academic Publishing AG & Co. KG

Book Chapters

Joiner KF; Efatmaneshnik M; Tutty M, 2019, 'Test and Evaluation Toolset', in Gorod A; Hallo L; Ireland V; Gunawan I (ed.), Evolving Toolbox for Complex Project Management, Auerbach Publications, Boca Raton, Florida, pp. 339 - 370

Kealy A; Alam N; Efatmaneshnik M; Toth C; Dempster A; Brzezinska D, 2014, 'Collaborative Positioning in GPS-Challenged Environments', in Rizos C; Willis P (ed.), Earth on the Edge: Science for a Sustainable Planet, edn. 139, Springer Berlin Heidelberg, pp. 493 - 500, http://dx.doi.org/10.1007/978-3-642-37222-3_66

Efatmaneshnik M; Alam N; Balaei AT; Kealy A; Dempster AG, 2012, 'Cooperative Positioning in Vehicular Networks', in Wireless Technologies in Vehicular Ad Hoc Networks: Present and Future Challenges, EGI Global, Mexico City, pp. 245 - 270, http://dx.doi.org/10.4018/978-1-4666-0209-0.ch012

Efatmaneshnik M; Reidsema C; Marczyk J; Balaei AT, 2010, 'Immune decomposition and decomposability analysis of complex design problems with a graph theoretic complexity measure', in Studies in Computational Intelligence, Springer Berlin Heidelberg, pp. 27 - 52, http://dx.doi.org/10.1007/978-3-642-04584-4_2

Efatmaneshnik M; Reidsema C, 2009, 'IMMUNE: A collaborating environment for complex system design', in Intelligent Systems Reference Library, edn. 1, pp. 275 - 320

Journal articles

Efatmaneshnik M, 2019, 'Editorial', Australian Journal of Multi-Disciplinary Engineering, vol. 15, pp. 1 - 1, http://dx.doi.org/10.1080/14488388.2019.1678849

Shoval S; Efatmaneshnik M, 2019, 'Managing Complexity of Assembly with Modularity: A Cost and Benefit Analysis', The International Journal of Advanced Manufacturing Technology, http://dx.doi.org/10.1007/s00170-019-03802-2

Efatmaneshnik M; Ryan MJ, 2019, 'On the Definitions of Sufficiency and Elegance in Systems Design', IEEE Systems Journal, vol. 13, pp. 2077 - 2088, http://dx.doi.org/10.1109/JSYST.2018.2875152

Efatmaneshnik M; Shoval S; Joiner KF, 2019, 'System Test Architecture Evaluation: A Probabilistic Modeling Approach', IEEE Systems Journal, vol. 13, pp. 3651 - 3666, http://dx.doi.org/10.1109/JSYST.2019.2899697

Efatmaneshnik M; Shoval S; Qiao L, 2018, 'A Standard Description of the Terms Module and Modularity for Systems Engineering', IEEE Transactions on Engineering Management, vol. Lili, http://dx.doi.org/10.1109/TEM.2018.2878589

Mabrok MA; Efatmaneshnik M; Ryan MJ, 2017, 'Integrating Nonfunctional Requirements Into Axiomatic Design Methodology.', IEEE Systems Journal, vol. 11, pp. 2204 - 2214, http://dx.doi.org/10.1109/JSYST.2015.2462073

Qiao L; Efatmaneshnik M; Ryan M; Shoval S, 2017, 'Product modular analysis with design structure matrix using a hybrid approach based on MDS and clustering', Journal of Engineering Design, vol. 28, pp. 1 - 1, http://dx.doi.org/10.1080/09544828.2017.1325858

Efatmaneshnik M; Joseph Bradely JB; Ryan MJ, 2016, 'Complexity and Fragility in System of Systems', International Journal of System of Systems Engineering, vol. 7, pp. 294 - 312, http://dx.doi.org/10.1504/IJSSE.2016.10001212

Shoval SS; Efatmaneshnik ME; Ryan MJ, 2016, 'Assembly sequence planning for processes with heterogeneous reliabilities', International Journal of Production Research, vol. 55, pp. 2204 - 2214, http://dx.doi.org/10.1080/00207543.2016.1213449

Efatmaneshnik M; Ryan MJ, 2016, 'A general framework for measuring system complexity', Complexity, vol. 21, pp. 533 - 546, http://dx.doi.org/10.1002/cplx.21767

Efatmaneshnik M; Ryan MJ, 2015, 'On optimal modularity for system construction', Complexity, vol. 21, pp. 176 - 189, http://dx.doi.org/10.1002/cplx.21646

Efatmaneshnik M; Alam N; Kealy A; Dempster AG, 2012, 'A fast multidimensional scaling filter for vehicular Cooperative Positioning', Journal of Navigation, vol. 65, pp. 223 - 243, http://dx.doi.org/10.1017/S0373463311000610

Li Y; Efatmaneshnik M; Dempster AG, 2012, 'Attitude determination by integration of MEMS inertial sensors and GPS for autonomous agriculture applications', GPS Solutions, vol. 16, pp. 41 - 52, http://dx.doi.org/10.1007/s10291-011-0207-y

Efatmaneshnik M; Kealy A; Balaei AT; Dempster AG, 2011, 'Information fusion for localization within vehicular networks', Journal of Navigation, vol. 64, pp. 401 - 416, http://dx.doi.org/10.1017/S0373463311000075

Efatmaneshnik ; Li Y; Dempster , 2011, 'Analysis of integrated navigation with GPS source variability', Coordinates, vol. VII, pp. 31 - 36, http://mycoordinates.org/analysis-of-integrated-navigation-with-gps-source-variability/

Efatmaneshnik M; Reidsema CA, 2010, 'A complex system engineering design model', Cybernetics and Systems (Online), vol. 41, pp. 554 - 576, http://dx.doi.org/10.1080/01969722.2010.520212

Efatmaneshnik M; Reidsema C, 2009, 'Decomposition, integration, and emergence in complex system design', Nonlinear Phenomena in Complex Systems, vol. 12, pp. 211 - 231

Efatmaneshnik M; Reidsema CA, 2007, 'Immunity as a design decision making paradigm for complex systems: a robustness approach', Cybernetics and Systems (Online), vol. 38, pp. 759 - 780, http://dx.doi.org/10.1080/01969720701601056

Conference Papers

Qiao LQ; Efatmaneshnik M; Ryan M, 2018, 'SMACOF Hierarchical Clustering to Manage Complex Design Problems with the Design Structure Matrix', in Advances in Intelligent Systems and Computing, Complex Systems Design and Management (CSD&M), Singapore, pp. 50 - 61, presented at Complex Systems Design and Management (CSD&M), Singapore, 09 December 2018 - 10 July 2018, http://dx.doi.org/10.1007/978-3-030-02886-2_5

Shoval SS; Efatmaneshnik M, 2018, 'A probabilistic approach to the Stochastic Job-Shop Scheduling problem', in Procedia Manufacturing, Elsevier, Haifa, Israel, pp. 533 - 540, presented at 15th Global Conference on Sustainable Manufacturing, Haifa, Israel, 25 September 2017 - 27 September 2017, http://dx.doi.org/10.1016/j.promfg.2018.02.154

Efatmaneshnik M; Handley HH, 2018, 'Revisiting Task Complexity: A Comprehensive Framework', in 12th Annual IEEE International Systems Conference, SysCon 2018 - Proceedings, Vancouver BC, pp. 1 - 4, presented at IEEE Systems Conference, Vancouver BC, 23 April 2018 - 26 April 2018, http://dx.doi.org/10.1109/SYSCON.2018.8369533

Joiner KF; Efatmaneshnik M; Tutty M, 2018, 'Modelling the Efficacy of Assurance Strategies for Better Integration, Interoperability and Information Assurance in Family-of-System-of-Systems Portfolios', in Advances in Intelligent Systems and Computing, Springer, Singapore, pp. 25 - 36, presented at Complex Systems Design & Management (CSD&M), Singapore, 06 December 2018 - 07 December 2018, http://dx.doi.org/10.1007/978-3-030-02886-2_3

Efatmaneshnik M; Ryan MJ, 2018, 'A Scenario Based Simulation Practice in Support of UAV Acquisition Process', in A Scenario Based Simulation Practice in Support of UAV Acquisition Process, Engineers Australia, Sydney, Australia, pp. 106 - 118, presented at Systems Engineering Test and Evaluation, Sydney, Australia, 29 April 2018 - 02 May 2018

Efatmaneshnik M; Ryan MJ; Shoval SS, 2018, 'A Framework for Testability Analysis from System Architecture Perspective', in A Framework for Testability Analysis from System Architecture Perspective, 28th Annual INCOSE International Symposium, Washington D.C., presented at 28th Annual INCOSE International Symposium, Washington D.C., 07 July 2018 - 12 July 2018, http://dx.doi.org/10.1002/j.2334-5837.2018.00518.x

Shoval SS; Efatmaneshnik M; Ryan MJ, 2017, 'Probabilistic Approach to Modular Assembly', in IFAC Proceedings Volumes (IFAC-PapersOnline), Elsevier, Toulouse, France, pp. 5688 - 5693, presented at 20th IFAC (International Federation of Automatic Control) World Congress, Toulouse, France, 09 July 2017 - 14 July 2017, http://dx.doi.org/10.1016/j.ifacol.2017.08.1119

Shoval SS; Efatmaneshnik M, 2017, 'A Proposal for Standardized Use of the Term “Module” in Systems Engineering', in INCOSE Proceedings, 27 th Annual INCOSE International Symposium (IS 2017), Wiley, Adelaide, SA, Australia, pp. 1291 - 1299, presented at INCOSE International Symposium, Adelaide, SA, Australia, 16 July 2017 - 21 July 2017, http://dx.doi.org/10.1002/j.2334-5837.2017.00428.x

Qiao L; Efatmaneshnik M; Ryan M, 2017, 'A Combinatorial Approach to Tradespace Exploration of Complex Systems: A CubeSat Case Study', in 27th Annual INCOSE International Symposium (IS 2017), 27th Annual INCOSE International Symposium (IS 2017), Adelaide, Australia, presented at 27th Annual INCOSE International Symposium (IS 2017), Adelaide, Australia, 15 July 2017 - 20 July 2017, http://dx.doi.org/10.1002/j.2334-5837.2017.00392.x

Rehman OU; Ryan M; Efatmaneshnik ME, 2017, 'Future Proofing Process', in INCOSE International Symposium, 27th Annual INCOSE International Symposium, Adelaide, Australia, presented at 27th Annual INCOSE International Symposium, Adelaide, Australia, 15 July 2017 - 20 July 2017, http://dx.doi.org/10.1002/j.2334-5837.2017.00403.x

Joiner KF; Efatmaneshnik M; Bradley JM; Keating CB, 2017, 'Evaluating Australia’s most complex system-of-systems, the future submarine: A case for using new Complex Systems Governance', in INCOSE International Symposium Proceedings, Wiley for INCOSE, Adelaide, Australia, July 15-20, 2017, pp. 187 - 199, presented at 27th Annual INCOSE International Symposium (IS 2017), Adelaide, Australia, July 15-20, 2017, 15 July 2017 - 17 July 2017, http://dx.doi.org/10.1002/j.2334-5837.2017.00353.x

Qiao L; Efatmaneshnik M; Ryan M, 2016, 'Tradespace Exploration for CubeSats Bus Design using Principal Component Analysis and K-medoids Clustering', in 16th Australian Space Research Conference proceedings 2016, National Space Society of Australia, RMIT university, Melbourne, Australia, presented at 16th Australian Space Research Conference, RMIT university, Melbourne, Australia, 26 September 2016 - 28 September 2016

Shoval S; Qiao L; Efatmaneshnik M; Ryan M, 2016, 'Dynamic Modular Architecture for Product Lifecycle', in Procedia CIRP, Elsevier, pp. 271 - 276, http://dx.doi.org/10.1016/j.procir.2016.03.037

Efatmaneshnik M; Ryan MR, 2016, 'A Study of Relationship between of System Testability and Modularity', in INCOSE International Symposium, INCOSE, Edinbrough, presented at INCOSE, Edinbrough, 18 July 2016 - 21 July 2016, http://dx.doi.org/10.1002/j.2334-5837.2016.00270.x

Efatmaneshnik M; Ryan M; Shoval , 2016, 'Modularization and Task Sequencing of Complex Assembly Systems', in 10th Annual International Systems Conference Proceedings, IEEE, Orlando, FL, pp. 56 - 61, presented at IEEE Systems Conference, Orlando, FL, 18 April 2016 - 21 April 2016, http://dx.doi.org/10.1109/SYSCON.2016.7490521

Efatmaneshnik M; Shoval , 2015, 'Upper and Lower Bound for Integration Cost of System with Heterogeneous Uncertainties', in Upper and Lower Bound for Integration Cost of System with Heterogeneous Uncertainties, 9th Asia-Pacific Conference on Systems Engineering (APCOSEC 2015), Seoul, Korea, presented at 9th Asia-Pacific Conference on Systems Engineering (APCOSEC 2015), Seoul, Korea, 13 October 2015 - 15 October 2015

Mabrok MA; Efatmaneshnik M; Ryan M, 2015, 'Including non-functional requirements in the Axiomatic Design process', in Systems Conference (SysCon), 2015 9th Annual IEEE International, pp. 54 - 60, presented at Systems Conference (SysCon), 2015 9th Annual IEEE International, 13 April 2015 - 16 April 2015, http://dx.doi.org/10.1109/SYSCON.2015.7116729

Bradley J; Efatmaneshnik M; Rajabalinejad M, 2015, 'A theory of complexity escalation and collapse for system of systems', in System of Systems Engineering Conference (SoSE), 2015 10th, pp. 7 - 11, presented at System of Systems Engineering Conference (SoSE), 2015 10th, 17 May 2015 - 20 May 2015, http://dx.doi.org/10.1109/SYSOSE.2015.7151958

Efatmaneshnik M; Ryan MU; Qaisar SU, 2015, 'System construction cost of hierarchical-modular structures', in 9th Annual IEEE International Systems Conference, SysCon 2015 - Proceedings, Vancouver, BC Canada, pp. 153 - 157, presented at 9th Annual IEEE International Systems Conference, Vancouver, BC Canada, 13 April 2015 - 16 April 2015, http://dx.doi.org/10.1109/SYSCON.2015.7116744

Efatmaneshnik M; Shoval , 2015, 'Ontological Description of Modules in System Design', in Yoshiaki Ohkami (ed.), APCOSE Proceedings, Asia and Pacific Conference on Systems Engineering, Seoul, Korea, presented at Asia and Pacific Conference on Systems Engineering, Seoul, Korea, 13 October 2015 - 15 October 2015

Bradley J; Efatmaneshnik M; Rajabalinejad M, 2015, 'Toward a theory of complexity escalation and collapse for system of systems', in Toward a theory of complexity escalation and collapse for system of systems

Efatmaneshnik M; Ryan MJ, 2015, 'Fundamentals of System Complexity Measures for Systems Design', in Fundamentals of System Complexity Measures for Systems Design

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