A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring

OZMEN, AHMET; Yalçın, Nesibe; balta, deniz

doi:10.3906/elk-1612-57

A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring

Nesibe YALÇIN, (Institute of Natural Sciences, Sakarya University, Sakarya, Turkey)

Deniz BALTA, (Department of Computer Engineering, Faculty of Computer and Information Sciences, Sakarya University, Sakarya, Turkey)

Ahmet ÖZMEN (Department of Computer Engineering, Faculty of Computer and Information Sciences, Sakarya University, Sakarya, Turkey)

Turkish Journal of Electrical Engineering and Computer Sciences

2 0

Yıl: 2018 Cilt: 26 Sayı: 3 Sayfa Aralığı: 1390 - 1402 Metin Dili: İngilizce DOI: 10.3906/elk-1612-57 İndeks Tarihi: 23-10-2018

A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring

Öz:

Hardware Trojans are one of the serious threats with detrimental, irreparable effects on the functionality, security, and performance of digital integrated circuits. It is difficult to detect Trojans because of their diversity in size and performance. While the majority of current methods focus on Trojan detection during chip testing, run-time techniques can be employed to gain unique advantages. This paper proposes a method based on the online scalable detection technique, which eliminates the need for a reference chip. Involving local detectors, this technique assesses the variations in the logical values of each node to find out whether there are Trojans. This method excludes time and power measurements, which are common parameters in most conventional methods. The detectors provide Trojanlocalization capability in our proposed technique. Two remarkable features of this technique are low power and low area overhead. The results are reported by simulation and implementation of common benchmarks, which show the high Trojan detection rate of the proposed method.

Anahtar Kelime:

Konular: Mühendislik, Elektrik ve Elektronik Bilgisayar Bilimleri, Yazılım Mühendisliği Bilgisayar Bilimleri, Sibernitik Bilgisayar Bilimleri, Bilgi Sistemleri Bilgisayar Bilimleri, Donanım ve Mimari Bilgisayar Bilimleri, Teori ve Metotlar Bilgisayar Bilimleri, Yapay Zeka

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık

Halgamuge MN, Chan TK, Mendis P. Ventilation efficiency and carbon dioxide (CO2) concentration. PIERS Online 2009; 5: 637-640.
Yalçın N, Balta D, Ozmen A. IAQ modeling and estimating for a meeting room. In: 2nd International Conference n Engineering and Natural Sciences; 24–28 May 2016; Sarajevo, Bosnia and Herzegovina. pp. 1075-1080.
Akal D. Indoor air pollution and negative effects on workers. Labour World 2013; 1: 112-119.
Robin E, Dodson E, Houseman A, Levy J, Bennet D, Shine J. Measured and modeled personal exposures to and risks from volatile organic compounds. Environ Sci Technol 2007; 41: 8498-8505.
Chen Y, Gu L, Zhang J. EnergyPlus and Champs-Multizone co-simulation for energy and indoor air quality analysis. Building Simulation 2015; 8: 371-380.
Tsujita W, Ishida H, Moriizumi T. Dynamic gas sensor network for air pollution monitoring and its auto-calibration. In: IEEE Sensors 2004; 2–5 November 2004; Valencia, Spain. New York, NY, USA: IEEE. pp. 56-59.
Ma QC, Zhou LB. CFD simulation study on gas dispersion for risk assessment: a case study of sour gas well blowout. Journal of Safety Science 2011; 49: 1289-1295.
Ramponi R, Blocken B. CFD simulation of cross-ventilation for a generic isolated building: impact of computational parameters. Build Environ 2012; 53: 34-48.
Blocken B, Stathopoulos T, Carmeliet J, Hensen JLM. Application of computational fluid dynamics in building performance simulation for the outdoor environment: an overview. Journal of Building Performance Simulation 2011; 4: 157-184.
Steeman HJ, Janssens A, Carmeliet J, De Paepe M. Modeling indoor air and hydrothermal wall interaction in building simulation: comparison between CFD and a well-mixed zonal model. Build Environ 2009; 44: 572-583.
Jurelionis A, Iseviˇcius E. CFD predictions of indoor air movement induced by cold window surfaces. J Civ Eng Manag 2008; 14: 29-38.
ASHRAE. Ventilation for Acceptable Indoor Air Quality. ANSI/ASHRAE Addendum p to ANSI/ASHRAE Standard 62.1-2013. Atlanta, GA, USA: ASHRAE, 2013.
Nassif N. CO2 -based demand-controlled ventilation control strategies for multi-zone HVAC systems. In: Proceedings of the Eleventh International Conference on Enhanced Building Operations 2011; 18–20 October 2011; New York, NY, USA.
Sarbu I, Sebarchievici C. Aspects of indoor environmental quality assessment in buildings. Energ Buildings 2013; 60: 410-19.
ASHRAE. Thermal Environmental Conditions for Human Occupancy, ANSI/ASHRAE Addendum g to ANSI/ASHRAE Standard 55-2010. Atlanta, GA, USA: ASHRAE, 2013.
Ibe CA, Anyanwu EE. Principles of Tropical Air Conditioning. Bloomington, IN, USA: AuthorHouse, 2013.
Scheff PA, Paulius VK, Huang SW, Conroy LM. Indoor air quality in a middle school, Part I: Use of CO2 as a tracer for effective ventilation. Applied Occupational and Environmental Hygiene 2000; 15: 824-834.
Ferreira AM, Cardoso M. Indoor air quality and health in schools. J Bras Pneumol 2014; 40: 259-268.
Ng MO, Qu M, Zheng P, Li Z, Hang Y. CO2 -based demand controlled ventilation under new ASHRAE Standard 62.1-2010: a case study for a gymnasium of an elementary school at West Lafayette, Indiana. Energ Buildings 2011;43: 3216-3225.
Sun Z, Wang S, Ma Z. In-situ implementation and validation of a CO2 -based adaptive demand-controlled ventilation strategy in a multi-zone office building. Build Environ 2011; 46: 124-133
Nassif N. A robust CO2 -based demand-controlled ventilation control strategy for multi-zone HVAC systems. Energ Buildings 2012; 45: 72-81.
Lu T, Lü X, Viljanen M. A novel and dynamic demand-controlled ventilation strategy for CO2 control and energy saving in buildings. Energ Buildings 2011; 43: 2499-2508.
Rackes A, Waring MS. Modeling impacts of dynamic ventilation strategies on indoor air quality of offices in six US cities. Build Environ 2013; 60: 243-253.
Cescatti A, Marcolla B, Goded I, Gruening C. Optimal use of buffer volumes for the measurement of atmospheric gas concentration in multi-point systems. Atmos Meas Tech 2016; 9: 4665-4672.
Noh K, Yook S. Evaluation of clean air delivery rates and operating cost effectiveness for room air cleaner and ventilation system in a small lecture room. Energ Buildings 2016; 119: 111-118.
Kulmala I, Salmela H, Kalliohaka T, Zweglinski T, Smolarkiewicz M, Taipale A, Kataja J. A tool for determining sheltering efficiency of mechanically ventilated buildings against outdoor hazardous agents. Build Environ 2016;106: 245-253.
Nazaroff WW. Mathematical modeling and control of pollutant dynamics in indoor air. PhD, California Institute of Technology, Pasadena, CA, USA, 1989.
Nazaroff WW, Cass GR. Mathematical modeling of indoor aerosol dynamics. Environ Sci Technol 1989; 23: 157-166.
Jamriska M. Modeling of indoor particle concentration. In: Morawska L, Salthammer T, editors. Indoor Environment-Airborne Particles and Settled Dust. New York, NY, USA: Wiley-VCH, 2003, pp. 319-330.
İncecik S. Hava Kirlili˘gi, 1st ed. ˙Istanbul, Turkey: ˙Istanbul Technical University Press, 1994 (in Turkish).
Jian Y, Guo Y, Liu J, Qingrui L. Case study of window opening behavior using field measurement results. Building Simulation 2010; 4: 107-116.
Bako-Biro Z, Clements-Croome DJ, Kochhar N, Awbi HB, Williams MJ. Ventilation rates in schools and pupils’ performance. Build Environ 2012; 48: 215-223.
Clements-Croome DJ, Awbi HB, Bako-Biro Z, Kochhar N, Williams M. Ventilation rates in schools. Build Environ 2008; 43: 362-367.
ASHRAE. Ventilation for Acceptable Indoor Air Quality. ASHRAE Standard 62-89. Atlanta, GA, USA: ASHRAE, 1989.
Kelly J. Hazard Evaluation of Carbon Dioxide Gas Release in Electro-Polish (EP) Room. Report. Newport News, VA, USA: Thomas Jefferson National Accelerator Facility, 2008.
Santamouris M, Synnefa A, Asssimakopoulos M, Livada I, Pavlou K, Papaglastra M, Gaitani N, Kolokotsa D, Assimakopoulos V. Experimental investigation of the air flow and indoor carbon dioxide concentration in classrooms with intermittent natural ventilation. Energ Buildings 2008; 40: 1833-1843.
Hayes SR. Use of an indoor air quality model (IAQM) to estimate indoor ozone levels. J Air Waste Manage 1991; 41: 161-170.
Hayes SR. Estimating the effect of being indoors on total personal exposure to outdoor air pollution. JAPCA J Air Waste Ma 1989; 39: 1453-1461.
Chaloulakoua A, Mavroidis I. Comparison of indoor and outdoor concentrations of CO at a public school. Evaluation of an indoor air quality model. Atmos Environ 2002; 36: 1769-1781.
Persily AK. Evaluating building IAQ and ventilation with indoor carbon dioxide. ASHRAE Tran 1997; 103: 4072.
Satish U, Mendel MJ, Shekhar K, Hotchi T, Sullivan D, Streufert S, Fisk WJ. Is CO2 an indoor pollutant? Direct effects of low-to-moderate CO2 concentrations on human decision-making performance. Environ Health Persp 2012; 120: 1671-1677.

APA	Yalçın N, balta d, OZMEN A (2018). A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. , 1390 - 1402. 10.3906/elk-1612-57
Chicago	Yalçın Nesibe,balta deniz,OZMEN AHMET A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. (2018): 1390 - 1402. 10.3906/elk-1612-57
MLA	Yalçın Nesibe,balta deniz,OZMEN AHMET A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. , 2018, ss.1390 - 1402. 10.3906/elk-1612-57
AMA	Yalçın N,balta d,OZMEN A A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. . 2018; 1390 - 1402. 10.3906/elk-1612-57
Vancouver	Yalçın N,balta d,OZMEN A A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. . 2018; 1390 - 1402. 10.3906/elk-1612-57
IEEE	Yalçın N,balta d,OZMEN A "A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring." , ss.1390 - 1402, 2018. 10.3906/elk-1612-57
ISNAD	Yalçın, Nesibe vd. "A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring". (2018), 1390-1402. https://doi.org/10.3906/elk-1612-57

APA	Yalçın N, balta d, OZMEN A (2018). A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. Turkish Journal of Electrical Engineering and Computer Sciences, 26(3), 1390 - 1402. 10.3906/elk-1612-57
Chicago	Yalçın Nesibe,balta deniz,OZMEN AHMET A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. Turkish Journal of Electrical Engineering and Computer Sciences 26, no.3 (2018): 1390 - 1402. 10.3906/elk-1612-57
MLA	Yalçın Nesibe,balta deniz,OZMEN AHMET A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. Turkish Journal of Electrical Engineering and Computer Sciences, vol.26, no.3, 2018, ss.1390 - 1402. 10.3906/elk-1612-57
AMA	Yalçın N,balta d,OZMEN A A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. Turkish Journal of Electrical Engineering and Computer Sciences. 2018; 26(3): 1390 - 1402. 10.3906/elk-1612-57
Vancouver	Yalçın N,balta d,OZMEN A A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring. Turkish Journal of Electrical Engineering and Computer Sciences. 2018; 26(3): 1390 - 1402. 10.3906/elk-1612-57
IEEE	Yalçın N,balta d,OZMEN A "A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring." Turkish Journal of Electrical Engineering and Computer Sciences, 26, ss.1390 - 1402, 2018. 10.3906/elk-1612-57
ISNAD	Yalçın, Nesibe vd. "A modeling and simulation study about CO2 amount with web-based indoor air quality monitoring". Turkish Journal of Electrical Engineering and Computer Sciences 26/3 (2018), 1390-1402. https://doi.org/10.3906/elk-1612-57