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Real-Time, Embedded, and Cyber-Physical Systems Research. Albert M. K. Cheng Professor Real-Time Systems Laboratory Department of Computer Science University of Houston, TX 77204, USA. Real-Time Systems Research Group. Director Prof. Albert M. K. Cheng PhD students
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Real-Time, Embedded, and Cyber-Physical Systems Research Albert M. K. Cheng Professor Real-Time Systems Laboratory Department of Computer Science University of Houston, TX 77204, USA
Real-Time Systems Research Group • Director Prof. Albert M. K. Cheng • PhD students Yong WoonAhn, Yu Li, XingliangZou, BehnazSanati, Sergio Chacon, Zeinab Kazemi, ChaitanyaBelwal (just graduated) • MS students Daxiao Liu, Yuanfeng Wen (just graduated), Fang Liu (just graduated) • Undergraduate students (NSF-REU) MozahidHaque, KalebChristoffersen, Dylan Thompson (just completed), James Hyatt (just completed) • Visiting Scholars Yu Jiang, Heilongjiang University, Harbin, China; Qiang Zhou (arriving in November 2013), Beihang University, Beijing, China Yu Li (Best Junior PhD Student Awardee and Friends of NSM Graduate Fellow) and Prof. Albert Cheng visit the NSF-sponsored Arecibo Observatory (world's largest and most sensitive radiotelescope) in Arecibo, Puerto Rico, after their presentation at the flagship RTSS 2012. Real-time systems research group at Yuanfeng Wen’s graduation party in May 2013.
An Embedded System or Real-Time System • Real-timesystem • Producescorrectresultsinatimelymanner. • Embeddedsystem • computer hardware and software embedded as part of a complete device or machine to perform one or more dedicated functions; often with real-time requirements. • Examples: • automotive control, avionics, medical systems, autonomous spacecrafts, industrial process control, mobile devices, and more.
Motivations and Applications: Automotive Control, Avionics, Medical Systems, and Many Embedded Systems
Old: Entire control process is done by mechanical hardware, governed by the mathematics of feedback control. Examples: Mastered cam grinder, Watt governor, Pneumatic process controller. New: Advances in electronics and computer systems lead to energetically isolate components of a controlled mechanical system. Masterless cam grinder, Digital oil production control of pump systems, Fly-by-wire airplane, Drive-by-wire automobile. Control Systems: Old and New
Components of a Modern Control and Monitoring System M Monitor/Instruments: Signal processing, Energy conversion User(s)/Operator(s) UI D T User Interface Decision and Control System: Computer Hardware, Software, Electronics Target System Under Control: Chemical/Fluid, Electrical, Mechanical, Thermal N Networking and Communication A Actuation: Energy conversion, Power modulation Other Components
Cyber-Physical System (CPS) • Tight conjoining of and coordination between computational and physical resources. • Significantly enhance the adaptability, autonomy, efficiency, functionality, reliability, safety, and usability of current control systems. • Example: An aerospace CPS will respond more quickly (e.g., automatic aircraft collision avoidance), are more precise (e.g., multiple landings in small airports), work in inaccessible environments (e.g., autonomous space exploration), provide large-scale, distributed coordination (e.g., automated air traffic control), are highly efficient (e.g., long-duration space travel), and augment human capabilities (e.g., tele-robotics).
Correctness of Real-Time Control and Monitoring Systems • Satisfaction of logical correctness constraints • Satisfaction of timing constraints
Design and Implementation Issues • Control and monitoring systems: old and new • Model of an embedded/real-time system • Scheduling real-time tasks • Rate-monotonic scheduler, EDF, LLF • Scheduling constraints • Multiprocessor scheduling • Identical, uniform, heterogeneous multiprocessors • Specification, verification, and debugging
Project 1: Determining Actual Response Time in Functional Reactive Systems • Ascertaining temporal properties is difficult • Execution time is dynamic in nature • Information known ‘a priori’ cannot be used • No notion of Critical Instance • Existing methods for preemptive execution cannot be applied • New methods are required
P-FRP Benefits • Type-safe programming language • Discrete and Continuous aspects • Transactional model prevents priority inversion • Synchronization primitives not required
Contribution • This work deals with finding actual response time in P-FRP • Actual time is not an approximate value • Actual time is found for a priori known release scenario • Method for finding actual response time is required for worst-case response time … … as well as developing exact schedulability tests and analyzing multi-processor schedulability.
Existing Approach: Audsley et al • Find response time of Task j • There will be no gaps till Task j completes • Utilization of system till Task j completes will be 1 • No task having lower priority than Task j will execute • Can be expressed as a Mathematical equality
Existing Approach: Audsley et al Iteration 1 : Iteration 2 : Iteration 3 : Iteration 4 :
Simulation • Execute for each discrete time unit • Computational cost dependent on response time • Data structures • Queue • Time • Overall computational cost is quite high
Gap Enumeration – Storage • Red-Black Tree • Self-balancing binary search tree • log2n time for insertion, delete and search
Gap Enumeration – Dynamic Size Iteration 1
Gap Enumeration – Dynamic Size Iteration 1
Experimental Analysis 7 Tasks
Experimental Analysis Difference vs. Response time - 7 Tasks
Worst-Case Response Time Combinatorial B-tree for generating release scenarios
Project 1: Conclusions and Ongoing Work • New method for response time computation • Polynomial-time approach to calculate WCRT • Optimal Priority Assignment in P-FRP’s execution model • Static Partitioning Schemes for symmetric multi-processors • Optimizing Energy Use • Enhancing Schedulability through reduced preemptions
Project 2: Real-Time Virtualization • Hierarchical real-time scheduling - Support large-scale systems - Provide isolation - Improve resource utilization • Real-time virtual resources - A virtual resource occupies a temporal partition of a physical resource
Magic7-Pfair-Mixed Algorithm and its Performance of Magic7 with 64 Resources, MaxReg=2
Project 3: Low Power Design for Real-Time Systems • Low power (energy) consumption is a key design for embedded systems • Battery’s life during operation. • Reliability. • Size of the system. • Power-aware real-time scheduling • Minimize the energy consumption • Power-aware scheduling for multiple feasible interval jobs. • Satisfy the real-time constraints. • Real-time Task Assignment on Rechargeable Multiprocessor System. • Reducing energy consumption in portable display devices
Dynamic Voltage Scaling (DVS) Technique for Real-Time Task • CPU’s energy/power consumption is a convex function of the CPU’s speed, e.g. P = CV2f-> P = s3. • Slowing down CPU’s speed reduces the energy usage for CPU. • Saving energy consumption V.S. Meeting deadline. • Reducing the CPU’s speed as much as possible while meeting every task’s deadline. • A minimum constant speed is always an optimal solution (if possible). • If more than one speed are needed, a “smooth” selection is better. • For regular single instance real-time jobs with only one feasible interval, Yao designed an algorithm for computing the optimal solution.
Considering power consumption for leakage current • As VLSI technology marches towards deep submicron and nanoscale circuits operating at multi-GHz frequencies, the rapidly elevated leakage power dissipation will soon become comparable to, if not exceeding, the dynamic power consumption: • Pleak = I leak V • P = Pdyn + Pleak • A critical speed s* = s where P(s) = P’(s)s • Shut down the CPU when it is idle. • Shut-downoverhead.
Real-time Task Assignment in Rechargeable Multiprocessor Systems • Scheduling of frame-based real-time tasks in partitioning schemes for multiprocessor systems powered by rechargeable batteries. • In frame-based real-time systems, a set of tasks must execute in a frame, and the whole frame is repeated. This system model is widely used in real-time communication, real-time imaging and a lot of other real-time/embedded systems, including medical systems. • The problem for uniprocessor system has been studied in [Allavena and Mosse 2001], in which an algorithm of complexity O(N) was proposed for determining the feasibility of a task set. • However, doing so in a rechargeable multiprocessor system is NP-Hard [Lin and Cheng 2008]. • We propose heuristic and approximation algorithms. Simulation results have shown that our algorithms exhibit very good behavior. Figure: Algorithm for rechargeable single processor [Allavena and Mosse 2001]
Real-time Task Assignment in Heterogeneous Distributed Systems with Rechargeable Batteries • Our techniques to solve the problem are based on four heuristics, namely Minimum Schedule Length (MSL), Min-min Schedule Length (MmSL), Genetic Algorithm (GA), and Ant Colony Optimization (ACO). • While the modifications of the MSL, MmSL and GA approaches from their original implementation are somewhat straight-forward, we design a novel structure using ACO. • Performance comparisons of these four techniques are performed and the results are discussed in [Lin and Cheng 2009].
RealEnergy:a New Framework and Tool to Evaluate Power-Aware Real-Time Scheduling Algorithms Intel XScale/PXA255 Module
Actual Energy Consumption Using DVS as meaured by RealEnergy
Concluding Remarks • Achieve higher QoS in real-time/embedded systems • Formal verification • Scheduling • New framework for CPS • Timing analysis of functional programs • Energy/Thermal-aware/Green computing • Evaluate systems with actual implementations and measurements • Virtualization and Resource Partitioning • Wireless, optical, and sensor networks • Deliver actual benefit to society
References • J. Lin and A. M. K. Cheng, “Maximizing Guaranteed QoS in (m,k)-firm Real-time Systems,” Proc. 12th IEEE International Conference on Embedded and Real-Time Computing Systems and Applications (RTCSA), Sydney, Australia, Aug. 2006. • J. Lin, Y. H. Chen, and A. M. K. Cheng, "On-Line Burst Header Scheduling in Optical Burst Switching Networks,'' Proc. 22nd IEEE International Conference on Advanced Information Networking and Applications (AINA), Okinawa, Japan, 2008. • J. Lin and A. M. K. Cheng, “Real-time Task Assignment in Recharegable Multiprocessor Systems,” Proc. 14th IEEE International Conference on Embedded and Real-Time Computing Systems and Applications (RTCSA), Kaohsiung, Taiwan, Aug. 2006. • J. Lin and A. M. K. Cheng, ``Real-time Task Assignment in Heterogeneous Distributed Systems with Rechargeable Batteries,'' IEEE International Conference on Advanced Information Networking and Applications (AINA), Bradford, UK, May 26-29, 2009. • J. Lin and A. M. K. Cheng, “Real-time Task Assignment with Replication on Multiprocessor Platforms," Proc. 15th IEEE International Conference on Parallel and Distributed Systems (ICPADS), Shenzhen, China, Dec. 8-11, 2009. • A. M. K. Cheng. Real-time systems: scheduling, analysis and verification. Wiley-Interscience, 2002. 2nd printing with updates, 2005. • A. M. K. Cheng, ``Applying (m, k)-firm Scheduling to Medical and Medication Systems,'' Workshop on Software and Systems for Medical Devices and Services (SMDS), in conjunction with IEEE-CS Real-Time Systems Symposium,Tucson, Arizona, Dec. 2007. • A. M. K. Cheng, ``Cyber-Physical Medical and Medication Systems,'' First International Workshop on Cyber-Physical Systems (WCPS2008), sponsored by the United States National Science Foundation, Beijing, China, June 20, 2008 (in conjunction with IEEE ICDCS 2008). • J. Ras and A. M. K. Cheng, ``Response Time Analysis for the Abort-and-Restart Event Handlers of the Priority-Based Functional Reactive Programming (P-FRP) Paradigm,'' Proc. 15th IEEE-CS International Conference on Embedded and Real-Time Computing Systems and Applications (RTCSA), Beijing, China, Aug. 2009. Nominated for Best Paper Award. • J. Lin and A. M. K. Cheng, ``Power-aware scheduling for Multiple Feasible Interval Jobs,'' Proc. 15th IEEE-CS International Conference on Embedded and Real-Time Computing Systems and Applications (RTCSA), Beijing, China, Aug. 2009. Nominated for Best Paper Award. • J. Lin, W. Song, A. M. K. Cheng ``RealEnergy: a New Framework and a Case Study to Evaluate Power-Aware Real-Time Scheduling Algorithms ,'' to appear in ACM International Symposium on Low Power Electronics and Design (ISLPED), Austin, Texas, USA, August 18-20, 2010.
References • Chaitanya Belwal and Albert M. K. Cheng, “Determining Actual Response Time in P-FRP,” Proc. Thirteenth International Symposium on Practical Aspects of Declarative Languages (PADL), Austin, Texas, USA, pages 250-264, January 24-25, 2011. • Chaitanya Belwal and Albert M. K. Cheng, “Determining Actual Response Time in P-FRP using Idle-Period Game Board,” Proc. 14th IEEE International Symposium on Object, Component, and Service-oriented Real-time Distributed Computing (ISORC), Newport Beach, CA, USA, pages 136-143, March 28-31, 2011. • Chaitanya Belwal and Albert M. K. Cheng, “Lazy vs Eager Conflict Detection in Software Transactional Memory: A Real-Time Schedulability Perspective,” IEEE Embedded Systems Letters, Vol. 3, No. 1, March 2011. • Chaitanya Belwal and Albert M. K. Cheng, “Scheduling Conditions for Real-time Software Transactional Memory,” to appear in IEEE Embedded Systems Letters, 2011. • Chaitanya Belwal and Albert M. K. Cheng, “An Extensible Framework for Real-time Task Generation and Simulation,” Proc. 17th IEEE International Conference on Embedded and Real-Time Computing Systems and Applications (RTCSA), Toyama, Japan, August 29-31, 2011. • Yuanfeng Wen, Albert M. K. Cheng, and Chaitanya Belwal, ``Worst Case Response Time for Real-Time Software Transactional Memory,'' to appear in ACM Research in Applied Computation Symposium (RACS) Poster Session, San Antonio, Texas, USA, October 23-26, 2012. • Yuanfeng Wen, Chaitanya Belwal, and Albert M. K. Cheng, ``Towards Optimal Priority Assignments for the Transactional Event Handlers of P-FRP,'' to appear in ACM International Conference on Reliable And Convergent Systems (RACS), Montreal, QC, Canada, October 1-4, 2013.
References • Chaitanya Belwal, Albert M. K. Cheng, and Yuanfeng Wen, ``Response Time Bounds for Event Handlers in the Priority based Functional Reactive Programming (P-FRP) Paradigm,'' to appear in ACM Research in Applied Computation Symposium (RACS), San Antonio, Texas, USA, October 23-26, 2012. • Chaitanya Belwal, Albert M. K. Cheng, and Yuanfeng Wen, ``Time Petri Nets for Schedulability Analysis of the Transactional Event Handlers of P-FRP,'' to appear in ACM Research in Applied Computation Symposium (RACS), San Antonio, Texas, USA, October 23-26, 2012. • Yuanfeng Wen, Ziyi Liu, Weidong Shi, Yifei Jiang, Albert M. K. Cheng, Feng Yang, and Abhinav Kohar, ``Support for Power Efficient Mobile Video Playback on Simultaneous Hybrid Display,'' to appear in 10th IEEE Symposium on Embedded Systems for Real-Time Multimedia (ESTIMedia), Tampere, Finland, October 11-12, 2012. • Yuanfeng Wen, Ziyi Liu, Weidong Shi, Yifei Jiang, Albert M. K. Cheng, and Khoa Le, ``Energy Efficient Hybrid Display and Predictive Models for Embedded and Mobile Systems,'' to appear in International Conference on Compilers, Architecture, and Synthesis for Embedded Systems (CASES), Tampere, Finland, October 7-12, 2012. • Stefan Andrei, Albert M. K. Cheng, Vlad Radulescu, and Timothy McNicholl, ``Toward an optimal power-aware scheduling technique,'' to appear in 14th International Symposium on Symbolic and Numeric Algorithms for Scientific Computing (SYNASC), Timisoara, Romania, September 26-29, 2012. • Weizhe Zhang and Albert M. K. Cheng, ``Performance Prediction of MPI Parallel Jobs in Cluster Environments,'' to appear in International Workshop on Power and QoS Aware Computing (PQoSCom), in conjunction with IEEE Cluster, Beijing, China, September 24-28, 2012. • Albert M. K. Cheng, Homa Niktab, and Michael Walston, ``Timing Analysis of Small Aircraft Transportation System (SATS),'' International Conference on Embedded and Real-Time Computing Systems and Applications (RTCSA), Seoul, Korea, August 2012.
References • Chaitanya Belwal, Albert M. K. Cheng, J. Ras, and Yuanfeng Wen, ``Variable Voltage Scheduling with the Priority-based Functional Reactive Programming Language,'' to appear in ACM International Conference on Reliable And Convergent Systems (RACS), Montreal, QC, Canada, October 1-4, 2013. • Albert M. K. Cheng, Stefan Andrei, and Mozahid Haque, ``Optimizing the Linear Real-Time Logic Verifier,'' 19th IEEE Real-Time and Embedded Technology and Applications Symposium (RTAS) WIP Session, Philadelphia, PA, April 8, 2013. • Yong woon Ahn and Albert M. K. Cheng, ``Autonomic Computing Architecture for Real-Time Medical Application Running on Virtual Private Cloud Infrastructures,'' 33rd Real-Time Systems Symposium (rtss) WIP Session, San Juan, Puerto Rico, USA, December 4-7, 2012. • Yu Li and Albert M. K. Cheng, `` Static Approximation Algorithms for Regularity-based Resource Partitioning,'' 33rd Real-Time Systems Symposium (RTSS), San Juan, Puerto Rico, USA, December 5-7, 2012.