Robust control and optimisation of energy consumption in daylight—artificial light integrated schemes

Kurian, Ciji Pearl; Aithal, Radhakrishna S; Bhat, Jayashree S.; George, V I

doi:10.1177/1477153507079511

Cited by 63 publications

(55 citation statements)

References 9 publications

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“…Advanced strategies are under development to integrate electric lighting systems and shading systems for optimal savings and comfort. 24 It is also a natural extension of the presented research to look into the interaction and integration with automatic shading controls.…”

Section: Conclusion and Discussionmentioning

confidence: 93%

Control of wireless-networked lighting in open-plan offices

Wen

Agogino

2010

Lighting Research & Technology

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This paper presents an energy-efficient lighting control system for open-plan offices with two novel features: A versatile 'plug-and-play' wireless-networked sensing and actuation system, and a control method incorporating multiple management strategies to provide occupant-specific lighting. Workstation-based wireless photosensors are employed to measure task illuminance, and individual addressability of wireless-enabled dimmable luminaires increases the freedom of the lighting system to fulfil various lighting requirements. Daylight harvesting, occupancy control and light level tuning strategies are formulated into an optimisation problem that generates light outputs for each luminaire to produce the desired lighting at each workstation with minimal energy usage. A pilot study of the wireless-networked lighting system implemented in a small open-plan office has shown more than 60% energy savings potential compared to conventional practice without any control.

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Section: Conclusion and Discussionmentioning

confidence: 93%

Control of wireless-networked lighting in open-plan offices

Wen

Agogino

2010

Lighting Research & Technology

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“…In addition, the scheme was so designed as to coordinate and control the automated electric lights as well as window blind systems as per user presence and user wishes. The simulation results (Kurian et al 2008a) carried out for tropical climates of Manipal, South India using test reference year (TRY) 2005 show that ANFIS dimming with a fuzzy logic based window blind controller provides complete optimization of thermal comfort and visual comfort including both glare control and uniformity in the interior with an annual energy savings of 23% − 49%. Whereas, ANFIS dimming with the fuzzy blind controller designed only for glare control show a increased annual energy saving of 35% − 60% according to window orientation.…”

Section: Daylight Responsive Dimming Systemsmentioning

confidence: 99%

“…An attempt has been made by Kurian et al (2008a) for applying simulation assisted computational model for adaptive predictive control in a daylight-artificial integrated scheme for energy saving, visual comfort, and thermal comfort. For maximizing energy saving while optimizing the performance and the quality of the visual environment the author proposes an integrated scheme comprising of: (i) a system identification approach for lighting control strategy, (ii) a fuzzy logic based window blind controller to reduce glare, increase uniformity and thermal comfort, and (iii) an adaptive predictive control scheme for the dimming of artificial light.…”

Section: Daylight Responsive Dimming Systemsmentioning

confidence: 99%

Prospective techniques of effective daylight harvesting in commercial buildings by employing window glazing, dynamic shading devices and dimming control—a literature review

et al. 2008

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Over a few decades, daylighting has been perceived to possess good potential for energy conservation. In this perspective, there have been significant advances in research methodologies and technologies for optimizing energy consumption through daylight harvesting in commercial buildings. In light of this, a thorough understanding of the application of available technology is very important for daylighting practices for building energy management. The objective of this paper is to examine the status of published research on three key building parameters: window glazing area, dynamic shading devices, and daylighting controls playing a rule on energy conservation. This article may serve as a coherent literature survey that would provide better understanding of the subjacent issues and possibly rejuvenate research interest in this immensely potential field of energy engineering.

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“…The predictive control system [18][19][20][21][22][23][24][25][26] here suggested has a three-level structure ( Figure 2): an upper layer with a control system (consisting of a pre-programmed software used according to predictive simulations performed thanks to software able to simulate the interaction between natural daylight with artificial sources and their illuminations levels); a middle layer where the control unit, with respect to the input provided by the twilight switch, regulates the dimming of the light sources; and, the third layer, which is the actual control, where the electronic on-board permits to regulate lighting sources to provide a proper illumination.…”

Section: Introductionmentioning

confidence: 99%

Management Optimization of the Luminous Flux Regulation of a Lighting System in Road Tunnels. A First Approach to the Exertion of Predictive Control Systems

et al. 2016

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Lighting very long road tunnels implies a high consumption of electrical energy since it requires a proper illumination during the whole day. In particular, in the daytime, the illuminance levels right at the tunnel entrance threshold and exit zones must be higher than those characterizing the inside of the tunnel; in this way, the eye of the driver is able to adapt and be safe while passing from a high natural illumination of the outside to the lighting conditions characterizing the inside of the tunnel. However this causes a high energy demand. Therefore, this case study investigates whether it is possible to minimize the energy demand through the exertion of an automatic new control system regulating the luminous fluxes of artificial sources (guaranteeing the parameters set by the regulation) with respect to the variation of the natural light characterizing the outside. The innovative control systems must be characterized by high reliability levels in order to guarantee conditions which are not dangerous to the driver if an outage occurs and minimize their maintenance costs. To carry out this type of study, the software DIALux was used to simulate a tunnel with a dimming system (with lamps characterized by a high luminous efficiency) regulated by a pre-programmed logic control system (with high Mean Time Between Failure (MTBF) values). The savings obtained enabled the amortization of the solution here suggested in a time interval that makes it an advantageous choice economically speaking.

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Robust control and optimisation of energy consumption in daylight—artificial light integrated schemes

Cited by 63 publications

References 9 publications

Control of wireless-networked lighting in open-plan offices

Control of wireless-networked lighting in open-plan offices

Prospective techniques of effective daylight harvesting in commercial buildings by employing window glazing, dynamic shading devices and dimming control—a literature review

Management Optimization of the Luminous Flux Regulation of a Lighting System in Road Tunnels. A First Approach to the Exertion of Predictive Control Systems

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