User-specific Skin Temperature-aware DVFS for Smartphones

Conference on Design Automation Test in Europe (DATE) (2015 : Grenoble, FRANCE)Skin temperature of mobile devices intimately affects the user experience. Power management schemes built into smartphones can lead to quickly crossing a user's threshold of tolerable skin temperature. Furthermore, there is a significant variation among users in terms of their sensitivity. Hence, controlling the skin temperature as part of the device's power management scheme is paramount. To achieve this, we first present a method for estimating skin and screen temperature at run-time using a combination of available on-device thermal sensors and performance indicators. In an Android-based smartphone, we achieve 99.05% and 99.14% accuracy in estimations of back cover and screen temperatures, respectively. Leveraging this run-time predictor, we develop User-specific Skin Temperature-Aware (USTA) DVFS mechanism to control the skin temperature. Performance of USTA is tested both with benchmarks and user tests comparing USTA to the standard Android governor. The results show that more users prefer to use USTA as opposed to the default DVFS mechanism

An Intelligent Framework for Energy-Aware Mobile Computing Subject to Stochastic System Dynamics

abstract: User satisfaction is pivotal to the success of mobile applications. At the same time, it is imperative to maximize the energy efficiency of the mobile device to ensure optimal usage of the limited energy source available to mobile devices while maintaining the necessary levels of user satisfaction. However, this is complicated due to user interactions, numerous shared resources, and network conditions that produce substantial uncertainty to the mobile device's performance and power characteristics. In this dissertation, a new approach is presented to characterize and control mobile devices that accurately models these uncertainties. The proposed modeling framework is a completely data-driven approach to predicting power and performance. The approach makes no assumptions on the distributions of the underlying sources of uncertainty and is capable of predicting power and performance with over 93% accuracy. Using this data-driven prediction framework, a closed-loop solution to the DEM problem is derived to maximize the energy efficiency of the mobile device subject to various thermal, reliability and deadline constraints. The design of the controller imposes minimal operational overhead and is able to tune the performance and power prediction models to changing system conditions. The proposed controller is implemented on a real mobile platform, the Google Pixel smartphone, and demonstrates a 19% improvement in energy efficiency over the standard frequency governor implemented on all Android devices.Dissertation/ThesisDoctoral Dissertation Computer Engineering 201

Efficient runtime management for enabling sustainable performance in real-world mobile applications

Mobile devices have become integral parts of our society. They handle our diverse computing needs from simple daily tasks (i.e., text messaging, e-mail) to complex graphics and media processing under a limited battery budget. Mobile system-on-chip (SoC) designs have become increasingly sophisticated to handle performance needs of diverse workloads and to improve user experience. Unfortunately, power and thermal constraints have also emerged as major concerns. Increased power densities and temperatures substantially impair user experience due to frequent throttling as well as diminishing device reliability and battery life. Addressing these concerns becomes increasingly challenging due to increased complexities at both hardware (e.g., heterogeneous CPUs, accelerators) and software (e.g., vast number of applications, multi-threading). Enabling sustained user experience in face of these challenges requires (1) practical runtime management solutions that can reason about the performance needs of users and applications while optimizing power and temperature; (2) tools for analyzing real-world mobile application behavior and performance. This thesis aims at improving sustained user experience under thermal limitations by incorporating insights from real-world mobile applications into runtime management. This thesis first proposes thermally-efficient and Quality-of-Service (QoS) aware runtime management techniques to enable sustained performance. Our work leverages inherent QoS tolerance of users in real-world applications and introduces QoS-temperature tradeoff as a viable control knob to improve user experience under thermal constraints. We present a runtime control framework, QScale, which manages CPU power and scheduling decisions to optimize temperature while strictly adhering to given QoS targets. We also design a framework, Maestro, which provides autonomous and application-aware management of QoS-temperature tradeoffs. Maestro uses our thermally-efficient QoS control framework, QScale, as its foundation. This thesis also presents tools to facilitate studies of real-world mobile applications. We design a practical record and replay system, RandR, to generate repeatable executions of mobile applications. RandR provides this capability by automatically reproducing non-deterministic input sources in mobile applications such as user inputs and network events. Finally, we focus on the non-deterministic executions in Android malware which seek to evade analysis environments. We propose the Proteus system to identify the instruction-level inputs that reveal analysis environments

TVFS: Topology Voltage Frequency Scaling for Reliable Embedded ConvNets

This brief introduces Topology Voltage Frequency Scaling (TVFS), a performance management technique for embedded Convolutional Neural Networks (ConvNets) deployed on low-power CPUs. Using TVFS, pre-trained ConvNets can be efficiently processed over a continuous stream of data, enabling reliable and predictable multi-inference tasks under latency constraints. Experimental results, collected from an image classification task built with MobileNet-v1 and ported into an ARM Cortex-A15 core, reveal TVFS holds fast and continuous inference (from few runs, up to 2000), ensuring a limited accuracy loss (from 0.9% to 3.1%), and better thermal profiles (average temperature 16.4 °C below the on-chip critical threshold)

Novel DVFS Methodologies For Power-Efficient Mobile MPSoC

Low power mobile computing systems such as smartphones and wearables have become an integral part of our daily lives and are used in various ways to enhance our daily lives. Majority of modern mobile computing systems are powered by multi-processor System-on-a-Chip (MPSoC), where multiple processing elements are utilized on a single chip. Given the fact that these devices are battery operated most of the times, thus, have limited power supply and the key challenges include catering for performance while reducing the power consumption. Moreover, the reliability in terms of lifespan of these devices are also affected by the peak thermal behaviour on the device, which retrospectively also make such devices vulnerable to temperature side-channel attack. This thesis is concerned with performing Dynamic Voltage and Frequency Scaling (DVFS) on different processing elements such as CPU & GPU, and memory unit such as RAM to address the aforementioned challenges. Firstly, we design a Computer Vision based machine learning technique to classify applications automatically into different categories of workload such that DVFS could be performed on the CPU to reduce the power consumption of the device while executing the application. Secondly, we develop a reinforcement learning based agent to perform DVFS on CPU and GPU while considering the user's interaction with such devices to optimize power consumption and thermal behaviour. Next, we develop a heuristic based automated agent to perform DVFS on CPU, GPU and RAM to optimize the same while executing an application. Finally, we explored the affect of DVFS on CPUs leading to vulnerabilities against temperature side-channel attack and hence, we also designed a methodology to secure against such attack while improving the reliability in terms of lifespan of such devices

Machine Learning for Resource-Constrained Computing Systems

Die verfügbaren Ressourcen in Informationsverarbeitungssystemen wie Prozessoren sind in der Regel eingeschränkt. Das umfasst z. B. die elektrische Leistungsaufnahme, den Energieverbrauch, die Wärmeabgabe oder die Chipfläche. Daher ist die Optimierung der Verwaltung der verfügbaren Ressourcen von größter Bedeutung, um Ziele wie maximale Performanz zu erreichen. Insbesondere die Ressourcenverwaltung auf der Systemebene hat über die (dynamische) Zuweisung von Anwendungen zu Prozessorkernen und über die Skalierung der Spannung und Frequenz (dynamic voltage and frequency scaling, DVFS) einen großen Einfluss auf die Performanz, die elektrische Leistung und die Temperatur während der Ausführung von Anwendungen. Die wichtigsten Herausforderungen bei der Ressourcenverwaltung sind die hohe Komplexität von Anwendungen und Plattformen, unvorhergesehene (zur Entwurfszeit nicht bekannte) Anwendungen oder Plattformkonfigurationen, proaktive Optimierung und die Minimierung des Laufzeit-Overheads. Bestehende Techniken, die auf einfachen Heuristiken oder analytischen Modellen basieren, gehen diese Herausforderungen nur unzureichend an. Aus diesem Grund ist der Hauptbeitrag dieser Dissertation der Einsatz maschinellen Lernens (ML) für Ressourcenverwaltung. ML-basierte Lösungen ermöglichen die Bewältigung dieser Herausforderungen durch die Vorhersage der Auswirkungen potenzieller Entscheidungen in der Ressourcenverwaltung, durch Schätzung verborgener (unbeobachtbarer) Eigenschaften von Anwendungen oder durch direktes Lernen einer Ressourcenverwaltungs-Strategie. Diese Dissertation entwickelt mehrere neuartige ML-basierte Ressourcenverwaltung-Techniken für verschiedene Plattformen, Ziele und Randbedingungen. Zunächst wird eine auf Vorhersagen basierende Technik zur Maximierung der Performanz von Mehrkernprozessoren mit verteiltem Last-Level Cache und limitierter Maximaltemperatur vorgestellt. Diese verwendet ein neuronales Netzwerk (NN) zur Vorhersage der Auswirkungen potenzieller Migrationen von Anwendungen zwischen Prozessorkernen auf die Performanz. Diese Vorhersagen erlauben die Bestimmung der bestmöglichen Migration und ermöglichen eine proaktive Verwaltung. Das NN ist so trainiert, dass es mit unbekannten Anwendungen und verschiedenen Temperaturlimits zurechtkommt. Zweitens wird ein Boosting-Verfahren zur Maximierung der Performanz homogener Mehrkernprozessoren mit limitierter Maximaltemperatur mithilfe von DVFS vorgestellt. Dieses basiert auf einer neuartigen {Boostability}-Metrik, die die Abhängigkeiten von Performanz, elektrischer Leistung und Temperatur auf Spannungs/Frequenz-Änderungen in einer Metrik vereint. % ignorerepeated Die Abhängigkeiten von Performanz und elektrischer Leistung hängen von der Anwendung ab und können zur Laufzeit nicht direkt beobachtet (gemessen) werden. Daher wird ein NN verwendet, um diese Werte für unbekannte Anwendungen zu schätzen und so die Komplexität der Boosting-Optimierung zu bewältigen. Drittens wird eine Technik zur Temperaturminimierung von heterogenen Mehrkernprozessoren mit Quality of Service-Zielen vorgestellt. Diese verwendet Imitationslernen, um eine Migrationsstrategie von Anwendungen aus optimalen Orakel-Demonstrationen zu lernen. Dafür wird ein NN eingesetzt, um die Komplexität der Plattform und des Anwendungsverhaltens zu bewältigen. Die Inferenz des NNs wird mit Hilfe eines vorhandenen generischen Beschleunigers, einer Neural Processing Unit (NPU), beschleunigt. Auch die ML Algorithmen selbst müssen auch mit begrenzten Ressourcen ausgeführt werden. Zuletzt wird eine Technik für ressourcenorientiertes Training auf verteilten Geräten vorgestellt, um einen konstanten Trainingsdurchsatz bei sich schnell ändernder Verfügbarkeit von Rechenressourcen aufrechtzuerhalten, wie es z.~B.~aufgrund von Konflikten bei gemeinsam genutzten Ressourcen der Fall ist. Diese Technik verwendet Structured Dropout, welches beim Training zufällige Teile des NNs auslässt. Dadurch können die erforderlichen Ressourcen für das Training dynamisch angepasst werden -- mit vernachlässigbarem Overhead, aber auf Kosten einer langsameren Trainingskonvergenz. Die Pareto-optimalen Dropout-Parameter pro Schicht des NNs werden durch eine Design Space Exploration bestimmt. Evaluierungen dieser Techniken werden sowohl in Simulationen als auch auf realer Hardware durchgeführt und zeigen signifikante Verbesserungen gegenüber dem Stand der Technik, bei vernachlässigbarem Laufzeit-Overhead. Zusammenfassend zeigt diese Dissertation, dass ML eine Schlüsseltechnologie zur Optimierung der Verwaltung der limitierten Ressourcen auf Systemebene ist, indem die damit verbundenen Herausforderungen angegangen werden

Power Consumption Analysis, Measurement, Management, and Issues:A State-of-the-Art Review of Smartphone Battery and Energy Usage

The advancement and popularity of smartphones have made it an essential and all-purpose device. But lack of advancement in battery technology has held back its optimum potential. Therefore, considering its scarcity, optimal use and efficient management of energy are crucial in a smartphone. For that, a fair understanding of a smartphone's energy consumption factors is necessary for both users and device manufacturers, along with other stakeholders in the smartphone ecosystem. It is important to assess how much of the device's energy is consumed by which components and under what circumstances. This paper provides a generalized, but detailed analysis of the power consumption causes (internal and external) of a smartphone and also offers suggestive measures to minimize the consumption for each factor. The main contribution of this paper is four comprehensive literature reviews on: 1) smartphone's power consumption assessment and estimation (including power consumption analysis and modelling); 2) power consumption management for smartphones (including energy-saving methods and techniques); 3) state-of-the-art of the research and commercial developments of smartphone batteries (including alternative power sources); and 4) mitigating the hazardous issues of smartphones' batteries (with a details explanation of the issues). The research works are further subcategorized based on different research and solution approaches. A good number of recent empirical research works are considered for this comprehensive review, and each of them is succinctly analysed and discussed

Power-Performance Modeling and Adaptive Management of Heterogeneous Mobile Platforms​

abstract: Nearly 60% of the world population uses a mobile phone, which is typically powered by a system-on-chip (SoC). While the mobile platform capabilities range widely, responsiveness, long battery life and reliability are common design concerns that are crucial to remain competitive. Consequently, state-of-the-art mobile platforms have become highly heterogeneous by combining a powerful SoC with numerous other resources, including display, memory, power management IC, battery and wireless modems. Furthermore, the SoC itself is a heterogeneous resource that integrates many processing elements, such as CPU cores, GPU, video, image, and audio processors. Therefore, CPU cores do not dominate the platform power consumption under many application scenarios. Competitive performance requires higher operating frequency, and leads to larger power consumption. In turn, power consumption increases the junction and skin temperatures, which have adverse effects on the device reliability and user experience. As a result, allocating the power budget among the major platform resources and temperature control have become fundamental consideration for mobile platforms. Dynamic thermal and power management algorithms address this problem by putting a subset of the processing elements or shared resources to sleep states, or throttling their frequencies. However, an adhoc approach could easily cripple the performance, if it slows down the performance-critical processing element. Furthermore, mobile platforms run a wide range of applications with time varying workload characteristics, unlike early generations, which supported only limited functionality. As a result, there is a need for adaptive power and performance management approaches that consider the platform as a whole, rather than focusing on a subset. Towards this need, our specific contributions include (a) a framework to dynamically select the Pareto-optimal frequency and active cores for the heterogeneous CPUs, such as ARM big.Little architecture, (b) a dynamic power budgeting approach for allocating optimal power consumption to the CPU and GPU using performance sensitivity models for each PE, (c) an adaptive GPU frame time sensitivity prediction model to aid power management algorithms, and (d) an online learning algorithm that constructs adaptive run-time models for non-stationary workloads.Dissertation/ThesisDoctoral Dissertation Electrical Engineering 201