EE 609: Convex
Optimization in SP/COM
- Instructors:
Ketan Rajawat
- Prerequisites:
Linear Algebra, Probability
- Objective:
Convex
optimization has recently been applied to a wide variety of problems in
EE,
especially in signal processing, communications, and networks. The aim
of this
course is to train the students in application and analysis of convex
optimization problems in signal processing and wireless communications.
At the
end of this course, the students are expected to:
- Know
about the applications of convex
optimization in signal processing, wireless communications, and
networking
research.
- Be
able to recognize convex optimization
problems arising in these areas.
- Be
able to recognize ‘hidden’ convexity
in many seemingly non-convex problems; formulate them as convex
problems.
- Be
able to develop low-complexity,
approximate solutions for difficult non-convex problems.
- References:
- Stephen Boyd and Lieven Vandenberghe, Convex
Optimization, Cambridge University Press. [Online]. http://www.stanford.edu/~boyd/cvxbook/
- Convex Optimization in Signal Processing and
Communications, D. P. Palomar, Y. C. Eldar. Cambridge Press, 2010.
- IEEE
Signal Processing Magazine- Special Issue on Advances in Convex
Optimization, Vol. 27, No. 3, May 2010.
- Dimitri P. Bertsekas, Convex Analysis and Optimization,
Athena-Scientific, 2003.
- Format
(tentative)
- Major quiz
(10) scheduled on Jan. 24 (Thursday) at 10am; venue L20
- Mid-sem exam (20) scheduled on TBA
- End-sem exam (35) scheduled
on TBA
- 7 Assignments (10): valid attempts
(correct or incorrect) will receive full credit
- 1 Term paper (25)
- Time and place:
Monday 11am, Thursday, Friday 10am, L-4
- This course will cover (approximately)
- Background on linear algebra
- Convex sets, functions, and problems
- Examples of convex problems: LP, QCQP, SOCP
- Duality, KKT conditions
- Geometric programming and applications
- Linear and quadratic classification
- Network optimization
- Sparse regression, Lasso, ridge regression and
applications in image processing
- Robust least squares and applications in signal processing
- Support vector machines and applications in machine
learning
- Semidefinite programming and applications in experiment
design
- Semidefinite relaxation and applications in MIMO
detection, integer programming
- Low rank matrix completion and applications in
recommendor systems
- Multidimensional scaling and applications in sensor
localization
- Numerical linear algebra, basics of interior point methods
- Tentative list of topics for Term Paper (only
sample papers are provided, others can also be chosen, specify:
theory/mixed/application mode)
- Online
learning and online convex optimization
- Shai
Shalev-Shwartz, Foundations and Trends in ML, 4(2), 2011
- Introduction
to Online optimization
- Elad
Hazan, Foundations and Trends in Optimization, 2(3-4), 2015
- Proximal
Algorithms
- Neal
Parikh and Stephen Boyd (2014), "Proximal Algorithms", Foundations and
Trends in Optimization: Vol. 1: No. 3, pp 127-239
- Multi-period
investment
- Stephen
Boyd, Mark T. Mueller, Brendan O’Donoghue and Yang Wang (2014),
"Performance Bounds and Suboptimal Policies for Multi–Period
Investment", Foundations and Trends in Optimization: Vol. 1: No.
1
- Stephen
Boyd, Enzo Busseti, Steve Diamond, Ronald N. Kahn, Kwangmoo Koh, Peter
Nystrup and Jan Speth (2017), "Multi-Period Trading via Convex
Optimization", Foundations and Trends in Optimization: Vol. 3: No.
1
- ADMM
- Stephen
Boyd, Neal Parikh, Eric Chu, Borja Peleato and Jonathan Eckstein
(2011), "Distributed Optimization and Statistical Learning via the
Alternating Direction Method of Multipliers", Foundations and Trends
in Machine Learning: Vol. 3: No. 1.
- Submodularity
and convexity
- Francis
Bach (2013), "Learning with Submodular Functions: A Convex Optimization
Perspective", Foundations and Trends in Machine Learning: Vol. 6: No.
2-3.
- Learning
over Networks
- Ali
H. Sayed (2014), "Adaptation, Learning, and Optimization over
Networks", Foundations and Trends® in Machine Learning: Vol. 7: No.
4-5, pp 311-801.
- S-lemma
- Polik,
I., Terlaky T., A Survey on the S-Lemma , SIAM Review Vol. 49, No. 3,
pp. 371-418, 2004.
- Derinkuyu,
K., Pinar, M., On the S-Procedure and Some Variants , 2004.
- Approximate
dynamic programming in transportation/logistics
- W.
B. Powell, H. Simao, B. Bouzaiene-Ayari, “Approximate Dynamic
Programming in Transportation and Logistics: A Unified Framework,”
European J. on Transportation and Logistics, Vol. 1, No. 3, pp. 237-284
(2012). DOI 10.1007/s13676-012-0015-8.
- Sequential
stochastic optimization, dynamic programming
- http://castlelab.princeton.edu/html/Papers/Powell-UnifiedFrameworkStochasticOptimization_July222017.pdf
- Clearing
the Jungle of Stochastic Optimization, Informs Tutorials in Operations
Research: Bridging Data and Decisions, pp. 109-137, November, 2014
- Robust
optimization in logistics (sample papers only, others can be used):
- Bertsimas
D., Thiele A. (2004) A Robust Optimization Approach to Supply Chain
Management. In: Bienstock D., Nemhauser G. (eds) Integer Programming
and Combinatorial Optimization. IPCO 2004. Lecture Notes in Computer
Science, vol 3064. Springer, Berlin, Heidelberg
- Bertsimas,
Dimitris, and Aurelie Thiele. "A robust optimization approach to
inventory theory." Operations research 54.1 (2006):
150-168.
- Ben-Tal,
Aharon, et al. "Retailer-supplier flexible commitments contracts: A
robust optimization approach." Manufacturing &
Service Operations Management 7.3 (2005): 248-271.
- Bertsimas,
Dimitris, and Melvyn Sim. "Tractable approximations to robust conic
optimization problems." Mathematical programming
107.1-2 (2006): 5-36.
- Subgradient
methods
- S.
Boyd and A. Mutapcic, Subgradient Methods , Notes for EE364b,
Stanford University, 2006. Available online.
- N.
Shor, Minimization Methods for
Non-Differentiable Functions , Springer Series in
Computational Mathematics, Springer, 1985.
- D.
Bertsekas, Nonlinear Programming. Athena Scientific, 1999.
- Robust
Optimization
- Bertsimas,
Dimitris, David B. Brown, and Constantine Caramanis. "Theory and
applications of robust optimization." SIAM review
53.3 (2011): 464-501.
- Robust
PCA
- Candes,
Emmanuel J., et al. "Robust principal component analysis?." Journal
of the ACM (JACM) 58.3 (2011): 11.
- Liu,
Guangcan, et al. "Robust recovery of subspace structures by low-rank
representation." IEEE Transactions on Pattern Analysis and
Machine Intelligence 35.1 (2013): 171-184.
- Wright,
John, et al. "Robust principal component analysis: Exact recovery of
corrupted low-rank matrices via convex optimization." Advances
in neural information processing systems.
2009.
- Xu,
Huan, Constantine Caramanis, and Sujay Sanghavi. "Robust PCA via
outlier pursuit." Advances in Neural Information Processing
Systems. 2010.
- Matrix
Completion
- Cai,
Jian-Feng, Emmanuel J. Candes, and Zuowei Shen. "A singular value
thresholding algorithm for matrix completion." SIAM Journal
on Optimization 20.4 (2010):
1956-1982.
- Candes,
Emmanuel J., and Benjamin Recht. "Exact matrix completion via convex
optimization." Foundations of Computational mathematics
9.6 (2009): 717.
- Lin,
Zhouchen, Minming Chen, and Yi Ma. "The augmented lagrange multiplier
method for exact recovery of corrupted low-rank matrices." arXiv
preprint arXiv:1009.5055
(2010).
- Candes,
Emmanuel J., and Terence Tao. "The power of convex relaxation:
Near-optimal matrix completion." IEEE Transactions on
Information Theory 56.5 (2010): 2053-2080.
- Coordinate
ascent/descent
- Yu.
Nesterov, Efficiency of coordinate descent methods on huge-scale
optimization problems, SIAM Journal on Optimization, 2012
- P.
Richt ́arik and M. Takac, Iteration complexity of randomized
block-coordinate descent methods for minimizing a composite function,
Mathematical Programming, 2014
- P.
Tseng and S. Yun, A coordinate gradient descent method for nonsmooth
separable minimization, Mathematical Programming, 2009
- Large-scale
optimization
- Feng
Niu, Benjamin Recht, Christopher Re, and Stephen Wright. Hogwild: A
lock-free approach to parallelizing stochastic gradient descent. In
Advances in neural information processing systems, pages 693–701, 2011
- Gemulla,
Rainer, et al. "Large-scale matrix factorization with distributed
stochastic gradient descent." Proceedings of the 17th ACM
SIGKDD international conference on Knowledge discovery and data mining.
ACM, 2011.
- Bottou,
Léon. "Large-scale machine learning with stochastic gradient descent." Proceedings
of COMPSTAT'2010. Physica-Verlag HD, 2010. 177-186.
- Semi-stochastic
methods:
- Konecny,
Jakub, and Peter Richtarik. "Semi-stochastic gradient descent methods."
arXiv preprint arXiv:1312.1666 (2013).
- Konecny,
Jakub, et al. "Mini-batch semi-stochastic gradient descent in the
proximal setting." IEEE Journal of Selected Topics in Signal
Processing 10.2 (2016): 242-255.
- Konecny,
Jakub, Zheng Qu, and Peter Richtarik. "Semi-stochastic coordinate
descent." Optimization Methods and Software 32.5
(2017): 993-1005.
- Konecny,
Jakub, Zheng Qu, and Peter Richtarik. "S2cd: Semi-stochastic coordinate
descent." NIPS Optimization in Machine Learning workshop.
2014.
- Stochastic
and online optimization
- A.
Nemirovski, A. Juditsky, G. Lan and A. Shapiro,Robust stochastic
approximation approach to stochastic programming, SIAM Journal on
Optimization (2009)
- Yu.
Nesterov, Primal-dual subgradient methods for convex problems,
Mathematical Programming (2009)
- L.
Xiao, Dual averaging methods for regularized stochastic learning and
online optimization, Journal of Machine Learning Research (2010)
- N.
Le Roux, M. Schmidt and F. Bach, A stochastic gradient method with an
exponential convergence rate for strongly convex optimization with
finite training sets, NIPS (2012)
- Variance
reduced stochastic gradient descent
- R.
Johnson and T. Zhang, Accelerating stochastic gradient descent using
predictive variance reduction NIPS (2013)
- L.
Xiao and T. Zhang, A proximal stochastic gradient method with
progressive variance reduction
- Defazio,
Aaron, Francis Bach, and Simon Lacoste-Julien. "SAGA: A fast
incremental gradient method with support for non-strongly convex
composite objectives." Advances in neural information
processing systems. 2014.
- Schmidt,
Mark, Nicolas Le Roux, and Francis Bach. "Minimizing finite sums with
the stochastic average gradient." Mathematical Programming
162.1-2 (2017): 83-112.
- Interior
point methods and self-concordant analysis
- S.
Boyd and L. Vandenberghe, Convex Optimization (2004), Chapter 9
- Proximal
point algorithms:
- O.
G ̈uler, On the convergence of the proximal point algorithm for convex
minimization, SIAM J. Control and Optimization (1991)
- O.
G ̈uler,New proximal point algorithms for convex minimization, SIOPT
(1992)
- O.
G ̈uler, Augmented Lagrangian algorithm for linear programming, JOTA
(1992)
- ADMM
variants
- D.
Goldfarb, S. Ma, K. Scheinberg, Fast alternating linearization methods
for minimizing the sum of two convex functions, (2010)
- T.
Goldstein and S. Osher, The split Bregman method for L1-regularized
problems, SIAM J. Imag. Sciences (2009)
- Dual
decomposition:
- F.
Kelly, A. Maulloo, D. Tan, Rate control in communication networks:
shadow prices, proportional fairness and stability, J. Operation
Research Society, 49 (1998).
- A.
Beck and M. Teboulle, Fast gradient-based algorithms for constrained
total variation image denoising and deblurring problems, IEEE
Transactions on Image Processing (2009)
- Subgradient
methods
- Nedic,
Angelia, and Asuman Ozdaglar. "Distributed subgradient methods for
multi-agent optimization." IEEE Transactions on Automatic Control 54.1
(2009): 48-61.
- Ram,
S. Sundhar, Angelia Nedić, and Venugopal V. Veeravalli. "Distributed
stochastic subgradient projection algorithms for convex optimization." Journal
of optimization theory and applications 147.3 (2010): 516-545.
- Tsitsiklis,
John, Dimitri Bertsekas, and Michael Athans. "Distributed asynchronous
deterministic and stochastic gradient optimization algorithms." IEEE
transactions on automatic control 31.9 (1986): 803-812.
- Smoothing
- Yu.
Nesterov, Smooth minimization of non-smooth functions, Mathematical
Programming (2005).
- Yu.
Nesterov, Excessive gap technique in nonsmooth convex minimization,
SIAM Journal on Optimization (2005)
- Majorization
Minimization
- Sun,
Ying, Prabhu Babu, and Daniel P. Palomar. "Majorization-minimization
algorithms in signal processing, communications, and machine learning."
IEEE Transactions on Signal Processing 65.3
(2017): 794-816.
- Figueiredo,
Mario AT, Jose M. Bioucas-Dias, and Robert D. Nowak.
"Majorization–minimization algorithms for wavelet-based image
restoration." IEEE Transactions on Image processing
16.12 (2007): 2980-2991.
- Mairal,
Julien. "Incremental majorization-minimization optimization with
application to large-scale machine learning." SIAM Journal on
Optimization 25.2 (2015): 829-855.
- Convex
optimization in Finance
- Yiyong
Feng and Daniel P. Palomar, A
Signal Processing Perspective on Financial Engineering, Foundations
and Trends in Signal Processing, Now Publishers, vol. 9, no. 1-2, 2016.
- Blind
deconvolution (Ken Ma
- Ahmed,
Ali, Benjamin Recht, and Justin Romberg. "Blind deconvolution using
convex programming." IEEE Transactions on Information Theory
60.3 (2014): 1711-1732.
- Chan,
Tsung-Han, et al. "A convex analysis framework for blind separation of
non-negative sources." IEEE Transactions on Signal Processing
56.10 (2008): 5120-5134.
- Gillis,
Nicolas, and Stephen A. Vavasis. "Fast and robust recursive
algorithmsfor separable nonnegative matrix factorization." IEEE
transactions on pattern analysis and machine intelligence
36.4 (2014): 698-714.
- Network
utility maximization (Palomar Chiang)
- Palomar,
Daniel Perez, and Mung Chiang. "A tutorial on decomposition methods for
network utility maximization." IEEE Journal on Selected Areas
in Communications 24.8 (2006):
1439-1451.
- Palomar,
Daniel P., and Mung Chiang. "Alternative distributed algorithms for
network utility maximization: Framework and applications." IEEE
Transactions on Automatic Control 52.12 (2007): 2254-2269.
- Congestion
control
- Steven
H. Low and David E.
Lapsley, “Optimization Flow
Control, I: Basic Algorithm and
Convergence,” IEEE/ACM Trans. on Networking, vol. 7,
no. 6, Dec. 1999.
- Steven
H. Low, Larry L.
Peterson, and Liming Wang,
“Understanding Vegas: a duality model,” Journal of
the ACM, vol. 49, no. 2, March 2002.
- Steven
H. Low, Fernando Paganini,
and John C. Doyle,
“Internet Congestion Control,” IEEE Control Systems
Magazine, Feb. 2002.
- Steven
H. Low, “A Duality Model of TCP and Queue Management Algorithms,”
IEEE/ACM Trans. on Networking, Oct. 2003.
- Segmentation
and multiview 3D reconstruction in image processing
- Daniel
Cremers, Thomas Pock, Kalin Kolev, and Antonin Chambolle, “Convex
Relaxation Techniques for Segmentation, Stereo and Multiview
Reconstruction” In Markov Random Fields for Vision and Image
Processing. MIT Press, 2011.
- Antonin
Chambolle, Daniel Cremers, and Thomas Pock,“A convex approach to
minimal partitions” SIAM Journal on Imaging Sciences. 5(4):1113–1158,
2012
- Kalin
Kolev, Maria Klodt, Thomas Brox, and Daniel Cremers,“Continuous global
optimization in multiview 3d reconstruction,” International Journal of
Computer Vision. 84(1):80–96, 2009.
- MIMO
linear transceiver design based on Schur convexity
- Daniel
P. Palomar, “A Unified Framework for Communications through
MIMO Channels,” Ph.D. dissertation, Technical University of
Catalonia, Barcelona, Spain, May 2003.
- Daniel
P. Palomar, “Convex Primal Decomposition for Multicarrier Linear MIMO
Transceivers,” IEEE Trans. on Signal Processing, Vol. 53, No. 12, pp.
4661-4674, Dec. 2005.
- Daniel
P. Palomar and Javier Fonollosa, “Algorithms for a Family of
Waterfilling Solutions,” IEEE Trans. on Signal Processing, Vol. 53, No.
2, pp. 686-695, Feb. 2005.
- Iterative
Waterfilling
- W.
Yu, W. Rhee, S. Boyd, and J. Cioffi, “Iterative Water-Filling for
Gaussian Vector Multiple-Access Channels,” IEEE Trans. on
Information Theory , vol. 50, no. 1, Jan. 2004.
- W.
Yu, “A Dual Decomposition Approach to the Sum Power Gaussian Vector
Multiple Access Channel Sum Capacity Problem,” in Proc. Conf. on
Information and Systems (CISS), The Johns Hopkins Univ., March 12-14,
2003.
- N.
Jindal, W. Rhee, S. Vishwanath, S. A. Jafar, and A. Goldsmith, “Sum
Power Iterative Water-Filling for Multi-Antenna Gaussian Broad cast
Channels,” IEEE Trans. on Information Theory , vol. 51, no. 4, April
2005.
- Daniel
P. Palomar, “Convex Primal Decomposition for Multicarrier Linear MIMO
Transceivers,” IEEE Trans. on Signal Processing , vol. 53,
no. 12, Dec. 2005.
- Minimax
approaches in MIMO
- Daniel
P. Palomar, John M. Cioffi, and Miguel A. Lagunas, “Uniform Power
Allocation in MIMO Channels: A Game-Theoretic Approach,” IEEE
Trans. on Information Theory, vol. 49, no. 7, July 2003.
- Antonio
Pascual-Iserte, Daniel P. Palomar, Ana P ́erez-Neira, Miguel A.
Lagunas, “A Robust Maximim Approach for MIMO Comm. with
Imperfect CSI Based on Convex Optimization,” IEEE Trans. on Signal
Processing, vol. 54, no. 1, Jan. 2006.
- Jiaheng
Wang and Daniel P. Palomar, “Worst-Case Robust Transmission in MIMO
Channels with Imperfect CSIT,” IEEE Trans. on Signal
Processing , vol. 57, no. 8, pp.
3086-3100, Aug. 2009.
- Game
theoretic communication system design
- Gesualdo
Scutari, Daniel P. Palomar, and Sergio Barbarossa, “Competitive Design
of Multiuser MIMO Systems based on Game Theory: A Unified View,” IEEE
JSAC: Special Issue on Game Theory , vol. 25, no. 7, Sept. 2008.
- Gesualdo
Scutari, Daniel P. Palomar, and Sergio Barbarossa, “Optimal Linear
Precoding Strategies for Wideband Noncooperative Systems Based on Game
Theory,” IEEE Trans. on Signal Processing , vol. 56, no. 3,
March 2008.
- Gesualdo
Scutari, Daniel P. Palomar, and Sergio Barbarossa , “Asynchronous
Iterative Water-Filling for Gaussian Frequency-Selective Interference
Channels,” IEEE Trans. on Information Theory, vol. 54, no. 7,
July 2008.
- Gesualdo
Scutari, Daniel P. Palomar, and Sergio Barbarossa, “Cognitive MIMO
Radio: A Competitive Optimality Design Based on Subspace
Projections,” IEEE Signal Processing Magazine, Nov. 2008.
- Signomial
Programming:
- Mung
Chiang, “Geometric programming
for communication systems,” Foundations and Trends
in Communications and Information Theory , Now Publishers,
vol. 2, no. 1-2, Aug. 2006.
- Mung
Chiang, Chee Wei Tan,
Daniel P. Palomar, Daniel
O’Neill, and David Julian, “Power Control
by Geometric Programming,” IEEE Trans. on Wireless
Communications, vol. 6, no. 7, pp.
2640-2651, July 2007
- Index
tracking in finance
- Benidis,
K., Feng, Y., and Palomar, D. P. (2017). Sparse Portfolios for
High-Dimensional Financial Index Tracking. IEEE Transactions on Signal
Processing
- Xu,
F., Xu, Z., and Xue, H., (2015). Sparse index tracking based on L1/L2
model and algorithm. arXiv preprint
- Jansen,
R., and Van Dijk, R. (2002). Optimal benchmark tracking with small
portfolios The Journal of Portfolio Management vol. 28, no. 2, pp.
33–39.
- Beasley,
J. E., Meade, N., and Chang, T.-J. (2003). An evolutionary heuristic
for the index tracking problem. European Journal of Operational
Research, vol. 148, no. 3, pp. 621–643.
- Scozzari,
A., Tardella, F., Paterlini, S., and, Krink, T. (2013). Exact and
heuristic approaches for the index tracking problem with UCITS
constraints. Annals of Operations Research, vol. 205, no. 1, pp.
235–250.
- Multiobjective
optimization and pareto optimality
- Marler,
R. Timothy, and Jasbir S. Arora. "Survey of multi-objective
optimization methods for engineering." Structural and multidisciplinary
optimization 26.6 (2004): 369-395.
- Desideri,
Jean-Antoine. "Multiple-gradient descent algorithm (MGDA) for
multiobjective optimization." Comptes Rendus Mathematique 350.5-6
(2012): 313-318.
- Fliege,
Jorg, and Benar Fux Svaiter. "Steepest descent methods for
multicriteria optimization." Mathematical Methods of
Operations Research 51.3 (2000): 479-494.
- Harada,
Ken, Jun Sakuma, and Shigenobu Kobayashi. "Local search for
multiobjective function optimization: pareto descent method."
Proceedings of the 8th annual conference on Genetic and evolutionary
computation. ACM, 2006.
- Fliege,
Joerg, LM Grana Drummond, and Benar Fux Svaiter. "Newton's method for
multiobjective optimization." SIAM Journal on Optimization 20.2 (2009):
602-626.
- Saddle
point methods for convex optimization
- Zhu,
Minghui, and Sonia Martínez. "On distributed convex optimization under
inequality and equality constraints." IEEE Transactions on Automatic
Control 57.1 (2012): 151-164.
- Chang,
Tsung-Hui, Angelia Nedić, and Anna Scaglione. "Distributed constrained
optimization by consensus-based primal-dual perturbation method." IEEE
Transactions on Automatic Control 59.6 (2014): 1524-1538.
- Integer
programming
- Park,
Jaehyun, and Stephen Boyd. "A semidefinite programming method for
integer convex quadratic minimization." Optimization Letters
(2017): 1-20.
- Marchand,
Hugues; Martin, Alexander; Weismantel, Robert; Wolsey, Laurence (2002).
"Cutting planes in integer and mixed integer programming" (PDF).
Discrete Applied Mathematics. 123: 387–446.
- Castro, J.;
Nasini, S.; Saldanha-da-Gama, F. (2017). "A
cutting-plane approach for large-scale capacitated multi-period
facility location using a specialized interior-point method"
- Bader, David
A.; Hart, William E.; Phillips, Cynthia A. (2004). "Parallel
Algorithm Design for Branch and Bound" (PDF). In
Greenberg, H. J. Tutorials on Emerging Methodologies and Applications
in Operations Research. Kluwer Academic Press.
- Distributed
Optimization
- A.
Nedic and A.
Ozdaglar. Distributed
subgradient methods for multi-agent optimization. IEEE
Transactions on Automatic Control , 54(1):48–61, Jan. 2009.
- J.
C. Duchi, A. Agarwal, and M. J. Wainwright. "Dual averaging for
distributed optimization: Convergence analysis and network scaling," IEEE Transactions on Automatic Control, 57(3):592–606, Mar.
2012
- E.
Wei and A.
Ozdaglar. Distributed
alternating direction method of
multipliers. In 51st IEEE
Annual Conference on Decision and Control, pages 5445–5450, Dec. 2012.
- J.
F. C. Mota, J. M. F. Xavier, P. M. Q. Aguiar, and M. Puschel. D-ADMM: A
communication-efficient distributed algorithm for separable optimization. IEEE Transactions on Signal Processing,
61(10):2718–2723, May 2013.
- W.
Shi, Q. Ling, K Yuan,
G Wu, and W
Yin. On the linear convergence
of the admm in decentralized consensus optimization. IEEE Transactions on Signal Processing , 62(7):1750–1761,
April 2014.
- Cross-layer
optimization in networks:
- Lin,
Xiaojun, Ness B. Shroff, and Rayadurgam Srikant. "A tutorial on
cross-layer optimization in wireless networks." IEEE Journal
on Selected areas in Communications 24.8 (2006):
1452-1463.
- Chiang,
Mung, et al. "Layering as optimization decomposition: A mathematical
theory of network architectures." Proceedings of the IEEE
95.1 (2007): 255-312.
- Georgiadis,
Leonidas, Michael J. Neely, and Leandros Tassiulas. "Resource
allocation and cross-layer control in wireless networks." Foundations
and Trends in Networking 1.1 (2006):
1-144.
- Lin,
Xiaojun, and Ness B. Shroff. "Joint rate control and scheduling in
multihop wireless networks." Decision and Control, 2004. CDC.
43rd IEEE Conference on. Vol. 2. IEEE, 2004.
- Convex
optimization in Control Theory
- Linear
Matrix Inequalities in System and Control Theory Stephen Boyd, Laurent
El Ghaoui, E. Feron, and V. Balakrishnan
- Linear
Controller Design – Limits of Performance, Stephen Boyd and Craig
Barratt
- Convex
optimization in Smart Grid
- Samadi,
Pedram, et al. "Optimal real-time pricing algorithm based on utility
maximization for smart grid." Smart Grid Communications
(SmartGridComm), 2010 First IEEE International Conference on. IEEE,
2010.
- Mohsenian-Rad,
Amir-Hamed, et al. "Autonomous demand-side management based on
game-theoretic energy consumption scheduling for the future smart
grid." IEEE transactions on Smart Grid 1.3 (2010):
320-331.
- Sortomme,
Eric, et al. "Coordinated charging of plug-in hybrid electric vehicles
to minimize distribution system losses." IEEE transactions on
smart grid 2.1 (2011): 198-205.
- Convex
optimization in robotics
- Verscheure,
Diederik, et al. "Time-optimal path tracking for robots: A convex
optimization approach." IEEE Transactions on Automatic Control
54.10 (2009): 2318-2327.
- Schulman,
John, et al. "Finding Locally Optimal, Collision-Free Trajectories with
Sequential Convex Optimization." Robotics: science and systems.
Vol. 9. No. 1. 2013.
- Zhu,
Minghui, and Sonia Martinez. "On distributed convex optimization under
inequality and equality constraints." IEEE Transactions on Automatic
Control 57.1 (2012): 151-164.
- Derenick,
Jason C., and John R. Spletzer. "Convex optimization strategies for
coordinating large-scale robot formations." IEEE Transactions on
Robotics 23.6 (2007): 1252-1259.
- Convex
optimization for motion planning
- Schulman,
John, et al. "Finding Locally Optimal, Collision-Free Trajectories with
Sequential Convex Optimization." Robotics: science and systems.
Vol. 9. No. 1. 2013.
- Prajna,
Stephen, Pablo A. Parrilo, and Anders Rantzer. "Nonlinear control
synthesis by convex optimization." IEEE Transactions on
Automatic Control 49.2 (2004): 310-314.
- Schulman,
John, et al. "Motion planning with sequential convex optimization and
convex collision checking." The International Journal of
Robotics Research 33.9 (2014): 1251-1270