+
+@inproceedings{belwal_variable_2013,
+ address = {New York, NY, USA},
+ series = {{RACS} '13},
+ title = {Variable {Voltage} {Scheduling} with the {Priority}-{Based} {Functional} {Reactive} {Programming} {Language}},
+ isbn = {978-1-4503-2348-2},
+ doi = {10.1145/2513228.2513271},
+ abstract = {In this paper, we consider how energy consumption can be reduced in the Priority-based Functional Reactive Programming (P-FRP) execution model through the implementation of Dynamic Voltage and Frequency Scaling (DVFS), a technique for modifying circuit delays and altering the operating frequency of the CPU. Use of DVFS can have an impact on task execution time, which adversely affects the temporal guarantees required from the real-time scheduler. Most of the existing studies provide solutions which are suitable for the classical model of preemptive task scheduling. Tasks which are schedulable in the preemptive model cannot be guaranteed to be schedulable in P-FRP, since the abort-based preemptive approach often creates additional costs in terms of response times.},
+ booktitle = {Proceedings of the 2013 {Research} in {Adaptive} and {Convergent} {Systems}},
+ publisher = {Association for Computing Machinery},
+ author = {Belwal, Chaitanya and Cheng, Albert M. K. and Ras, J. and Wen, Yuanfeng},
+ year = {2013},
+ note = {event-place: Montreal, Quebec, Canada},
+ keywords = {embedded system, real-time},
+ pages = {440--445},
+}
+
+@article{alhirabi_security_2021,
+ title = {Security and {Privacy} {Requirements} for the {Internet} of {Things}: {A} {Survey}},
+ volume = {2},
+ issn = {2691-1914},
+ url = {https://doi.org/10.1145/3437537},
+ doi = {10.1145/3437537},
+ abstract = {The design and development process for internet of things (IoT) applications is more complicated than that for desktop, mobile, or web applications. First, IoT applications require both software and hardware to work together across many different types of nodes with different capabilities under different conditions. Second, IoT application development involves different types of software engineers such as desktop, web, embedded, and mobile to work together. Furthermore, non-software engineering personnel such as business analysts are also involved in the design process. In addition to the complexity of having multiple software engineering specialists cooperating to merge different hardware and software components together, the development process requires different software and hardware stacks to be integrated together (e.g., different stacks from different companies such as Microsoft Azure and IBM Bluemix). Due to the above complexities, non-functional requirements (such as security and privacy, which are highly important in the context of the IoT) tend to be ignored or treated as though they are less important in the IoT application development process. This article reviews techniques, methods, and tools to support security and privacy requirements in existing non-IoT application designs, enabling their use and integration into IoT applications. This article primarily focuses on design notations, models, and languages that facilitate capturing non-functional requirements (i.e., security and privacy). Our goal is not only to analyse, compare, and consolidate the empirical research but also to appreciate their findings and discuss their applicability for the IoT.},
+ number = {1},
+ journal = {ACM Trans. Internet Things},
+ author = {Alhirabi, Nada and Rana, Omer and Perera, Charith},
+ month = feb,
+ year = {2021},
+ note = {Place: New York, NY, USA
+Publisher: Association for Computing Machinery},
+ keywords = {design principles, Internet of Things, non functional requirements, notation, software design tools, software engineering},
+ file = {Alhirabi et al. - 2021 - Security and Privacy Requirements for the Internet.pdf:/home/mrl/.local/share/zotero/storage/7UN4IF62/Alhirabi et al. - 2021 - Security and Privacy Requirements for the Internet.pdf:text/html},
+}