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Building Lighting Automation through the Integration of DALI
INTERNATIONAL JOURNAL OF PROFESSIONAL ENGINEERING STUDIES Volume II/Issue 1/JAN2014 Building Lighting Automation through the Integration of DALI With Wireless Sensor Networks 1 V.Sivaparvathi 1, P.Sudhakar Rao 2 M.Tech Student, Dept of ECE, Nova College of Engineering & Technology for Women, Jupudi villaga, Ibrahimpatnam mandal, Krishna Dist, A.P, India 2 Assistant Professor, Dept of ECE, Nova College of Engineering & Technology for Women, Jupudi villaga, Ibrahimpatnam mandal, Krishna Dist, A.P, India Abstract: A building automation system deals with monitoring and control of building services, such as light, Fan, LED, alarms, etc. Wireless communication is the transfer of information over a distance without the use of electrical conductors or wires. The distances involved may be short (a few meters as in television remote control) or long (thousands or millions of kilometers for radio communications).It encompasses various types of fixed, mobile, and portable two-way radios, cellular telephones, personal digital assistants (PDAs), and wireless networking. We tested Zigbee networks in various environmental conditions by using four node star networks for industrial applications like speed and direction control of D.C motor, Illumination control of incandescent lamp and closed loop water path temperature control. It was seen that error free proper communication was established between the processing unit and monitoring unit. In future we can also test other Zigbee Networks for proper wireless data communication. Key words: ZIGBEE wireless technology, GSM Modem, Sensors, Control devices. its beginning, BA’s purpose was the comfort of end consumers and afterwards (early 1970s), energy efficiency criteria were also considered. Even though other home systems like lighting should also use automation, they are usually installed in a different system than HVAC. This division of the two subsystems increases the end consumer cost due to additional investment in communication hardware and software for integrating and lighting in a single control point. As it was previously stated, building services are usually controlled separately, making BA the set of control and communication technologies which link those different subsystems and make them work from a centralized monitoring and control center. The main purpose of having a single control point which provides access to all building services is the costs reduction. A remote monitoring allows the quick detection of failing devices without needing long searches and wasting personal time. This continuous monitoring enables a preventive, or predictive as well, maintenance, which results in a reduction of operational and maintenance costs. Since it is estimated that the operational cost of a building is about seven times the initial investment, taking into consideration the global life-cycle an additional initial cost is worth the effort. I. Introduction II. The Hardware System A building automation (BA) system (BAS) deals with monitoring and control of building services, such as heating, ventilation and air conditioning (HVAC), lighting, alarms, etc. Not only is it the system bound to operate in HVAC appliances and lamps, but HVAC and lighting control can also be obtained by more natural and efficient ways, e.g. starting a motor to open blinds. BAS were initially developed to control HVAC systems. Through time we have gone through several kinds of controllers, e.g. pneumatics, analog circuits, microprocessors, etc. At the time of Micro controller: This section forms the control unit of the whole project. This section basically consists of a Microcontroller with its associated circuitry like Crystal with capacitors, Reset circuitry, Pull up resistors (if needed) and so on. The Microcontroller forms the heart of the project because it controls the devices being interfaced and communicates with the devices according to the program being written. IJPRES ARM7TDMI: ARM is the abbreviation of Advanced RISC Machines, it is the name of a class of 12 INTERNATIONAL JOURNAL OF PROFESSIONAL ENGINEERING STUDIES processors, and is the name of a kind technology too. The RISC instruction set, and related decode mechanism are much simpler than those of Complex Instruction Set Computer (CISC) designs. GSM Modem: GSM/GPRS RS232 Modem from rhydo LABZ is built with sim com Make SIM900 Quad-band GSM/GPRS engine, works on frequencies 850 MHz, 900 MHz, 1800 MHz and 1900 MHz It is very compact in size and easy to use as plug in GSM Modem. ZIGBEE: ZIGBEE is a new wireless technology guided by the IEEE 802.15.4 Personal Area Networks standard. It is primarily designed for the wide ranging automation applications and to replace the existing non-standard technologies. It currently operates in the 868MHz band at a data rate of 20Kbps in Europe, 914MHz band at 40Kbps in the USA, and the 2.4GHz ISM bands Worldwide at a maximum data-rate of 250Kbps. Volume II/Issue 1/JAN2014 data communication. Fig.1.Transmitter section Temperature sensor: Temperature sensors are devices used to measure the temperature of a medium. Examples of this include maintaining the temperature of a chemical reactor at the ideal setpoint, monitoring the temperature of a possible runaway reaction to ensure the safety of employees, and maintaining the temperature of streams released to the environment to minimize harmful environmental impact. Light sensor: we use the light sensor to measure the light intensity in the environment. III. Design of Proposed Hardware System A building automation system deals with monitoring and control of building services, such as light, Fan, LED, alarms, etc. Wireless communication is the transfer of information over a distance without the use of electrical conductors or wires. The distances involved may be short (a few meters as in television remote control) or long (thousands or millions of kilometers for radio communications).It encompasses various types of fixed, mobile, and portable two-way radios, cellular telephones, personal digital assistants (PDAs), and wireless networking. We tested ZIGBEE networks in various environmental conditions by using four node star networks for industrial applications like speed and direction control of D.C motor, Illumination control of incandescent lamp and closed loop water path temperature control. It was seen that error free proper communication was established between the processing unit and monitoring unit. In future we can also test other ZIGBEE Networks for proper wireless IJPRES Fig.2.Receiver section Here we are going to develop a wireless technology for data acquisition of parameters like lighting control, temperature control etc in a building. In this system we are monitoring the data for temperature and light present in a Building, here a GSM modem is also used to control the parameters through mobile, the data regarding temperature, light is displayed in a LCD. The transmit ion of data is done using a ZIGBEE transceiver through micro controller. This data is received by ZIGBEE receiver and displays it in LCD in the monitoring section which will be with a person in that building. Using this data the operator can control the devices by giving the necessary commands, this commands are received by control devices in the processing unit and performs the operations. If any fault occurs the sensors detects the error and makes the buzzer to buzz. Simultaneously it also sends a message to mobile and we can also control with our mobile by sending a message. This message is received by the 13 INTERNATIONAL JOURNAL OF PROFESSIONAL ENGINEERING STUDIES GSM modem through micro controller and performs the operations in emergency conditions like any fault occurs or in normal conditions, like to switch on the fan (or) a bulb. IV. Board Hardware Resources Features ZIGBEE Technology The ZIGBEE specification is a combination of Home RF Late and the 802.15.4 specification. The specification operates in the 2.4GHz (ISM) radio band - the same band as 802.11b standard, Bluetooth, microwaves and some other devices. It is capable of connecting 255 devices per network. The specification supports data transmission rates of up to 250 Kbps at a range of up to 30 meters. ZIGBEE's technology is slower than 802.11b (11 Mbps) and Bluetooth (1 Mbps) but it consumes significantly less power. 802.15.4 (ZIGBEE) is a new standard uniquely designed for low rate wireless personal area networks. It targets low data rate, low power consumption and low cost wireless networking, and its goal is to provide a physical-layer and MAC-layer standard for such networks. Wireless networks provide advantages in deployment, cost, size and distributed intelligence when compared with wired networks. This technology allows users to set up a network quickly, and allows them to set up networks where it is impossible or inconvenient to wire cables. Wireless networks are more cost-efficient than wired networks in general. Bluetooth (802.15.1) was the first wellknown wireless standard facing low data rate applications. The effort of Bluetooth to cover more applications and provide quality of service has led to its deviation from the design goal of simplicity, which makes it expensive and inappropriate for some simple applications requiring low cost and low power consumption. These are the kind of applications this new standard is focused on. It's relevant to compare here Bluetooth and ZIGBEE, as they are sometimes seen as competitors, to show their differences and to clarify for which applications suits each of them. The data transfer capabilities are much higher in Bluetooth, which is capable of transmitting audio, graphics and pictures over small networks, and also appropriate for file transfers. ZIGBEE, on the other hand, is better suited for transmitting smaller packets over large networks; mostly static networks with many, infrequently used devices, like home automation, toys, remote controls, etc. While the performance of a Bluetooth network drops when more than 8 devices are present, ZIGBEE networks can handle 65000+ devices. IJPRES Volume II/Issue 1/JAN2014 GSM Module GSM (Global System for Mobile communication) is a digital mobile telephone system that is widely used in many parts of the world. The mobile communications has become one of the driving forces of the digital revolution. Every day, millions of people are making phone calls by pressing a few buttons. Little is known about how one person's voice reaches the other person's phone that is thousands of miles away. Even less is known about the security measures and protection behind the system. The complexity of the cell phone is increasing as people begin sending text messages and digital pictures to their friends and family. The cell phone is slowly turning into a handheld computer. All the features and advancements in cell phone technology require a backbone to support it. The system has to provide security and the capability for growth to accommodate future enhancements. General System for Mobile Communications, GSM, is one of the many solutions out there. GSM has been dubbed the "Wireless Revolution" and it doesn't take much to realize why GSM provides a secure and confidential method of communication. GSM (Global System for Mobile communication) is a digital mobile telephone system that is widely used in many parts of the world. GSM uses a variation of Time Division Multiple Access (TDMA) and is the most widely used of the three digital wireless telephone technologies (TDMA, GSM, and CDMA). GSM digitizes and compresses data, then sends it down a channel with two other streams of user data, each in its own time slot. GSM operates in the 900MHz, 1800MHz, or 1900 MHz frequency bands. GSM has been the backbone of the phenomenal success in mobile telecoms over the last decade. Now, at the dawn of the era of true broadband services, GSM continues to evolve to meet new demands. One of GSM's great strengths is its international roaming capability, giving consumers a seamless service. This has been a vital driver in growth, with around 300 million. In the Americas, today's 7 million subscribers are set to grow rapidly, with market potential of 500 million in population, due to the introduction of GSM 800, which allows operators using the 800 MHz band to have access to GSM technology too. GSM together with other technologies is part of an evolution of wireless mobile telecommunication that includes High-Speed Circuit-Switched Data (HCSD), General Packet Radio System (GPRS), Enhanced Data GSM Environment (EDGE), and Universal Mobile Telecommunications Service (UMTS). GSM 14 INTERNATIONAL JOURNAL OF PROFESSIONAL ENGINEERING STUDIES security issues such as theft of service, privacy, and legal interception continue to raise significant interest in the GSM community. The purpose of this portal is to raise awareness of these issues with GSM security. The mobile communications has become one of the driving forces of the digital revolution. Every day, millions of people are making phone calls by pressing a few buttons. Little is known about how one person's voice reaches the other person's phone that is thousands of miles away. Even less is known about the security measures and protection behind the system. The complexity of the cell phone is increasing as people begin sending text messages and digital pictures to their friends and family. The cell phone is slowly turning into a handheld computer. All the features and advancements in cell phone technology require a backbone to support it. The system has to provide security and the capability for growth to accommodate future enhancements. General System for Mobile Communications, GSM, is one of the many solutions out there. GSM has been dubbed the "Wireless Revolution" and it doesn't take much to realize why GSM provides a secure and confidential method of communication. Volume II/Issue 1/JAN2014 Fig.4. Temperature sensor Working of LM35: 1. It has an output voltage that is proportional to the Celsius temperature. 2. The scale factor is .01V/oC 3. The LM35 does not require any external calibration or trimming and maintains an accuracy of +/-0.4 oC at room temperature and +/- 0.8 oC over a range of 0 oC to +100 o C. 4. Another important characteristic of the LM35DZ is that it draws only 60 micro amps from its supply and possesses a low self-heating capability. The sensor selfheating causes less than 0.1 oC temperature rise in still air. The LM35 comes in many different packages, including the following. TO-92 plastic transistor-like package, T0-46 metal can transistor-like package 8-lead surface mount SO-8 small outline package TO-202 package. (Shown in the picture above) Fig.3. General architecture of a GSM network Temperature Sensor - The LM35 The LM35 is an integrated circuit sensor that can be used to measure temperature with an electrical output proportional to the temperature (in oC) The LM35 - An Integrated Circuit Temperature Sensor You can measure temperature more accurately than a using a thermistor. The sensor circuitry is sealed and not subject to oxidation, etc. The LM35 generates a higher output voltage than thermocouples and may not require that the output voltage be amplified. LDR: LDRs or Light Dependent Resistors are very useful especially in light/dark sensor circuits. Normally the resistance of an LDR is very high, sometimes as high as 1000 000 ohms, but when they are illuminated with light resistance drops dramatically. Fig.5. LDR sensor IJPRES 15 INTERNATIONAL JOURNAL OF PROFESSIONAL ENGINEERING STUDIES The animation opposite shows that when the torch is turned on, the resistance of the LDR falls, allowing current to pass through. V. Conclusion A new remote management system for buildings lighting automation has been presented. With the use of wireless sensor networks we could be able to extend DALI initial capacity of 64 devices to a number big enough to be used in real scenarios such as residential areas and large buildings without additional investments in different DALI loop. The control through the PAN coordinator of the wireless sensor network also enables a centralized control system. The use of DALI devices with wireless sensor network allows a half-duplex communication which can provide many parameters about the lighting and lamp status, this is very useful for saving energy and maintenance purposes, as it can detect any single lamp fault allowing a predictive maintenance and group replacement or schedule power consumptions rules enabling the integration of the lighting system in home and buildings into Smart Grid approaches, since we can monitor and act over them. Future work will include a comparative study between the proposed system and other wired system, focusing on energy efficiency, Smart Grid capabilities and installation and maintenance costs. We will take also into consideration the higher flexibility of wireless systems against wired systems. Further implementations will be done in order to extend the proposed system to other standards or technologies of lamps, luminaries or lightning communication and control protocols. Finally, the application or User Interface may be developed in deep in order to support functionality for Smart Grid at home and buildings, for energy saving and for its integration into a broad Home Automation or Building Automation scenario, pursuing also the improvement of the user experience. REFERENCES [1] W. Kastner, G. Neugschwandtner, S. Soucek, and H. M. Newmann, “Communication systems for building automation and control,” Proc. IEEE, vol. 93, no. 6, pp. 1178-1203, Jun. 2005. [2] D. Snoonian, “Smart buildings,” IEEE Spectr., vol. 40, no. 8, pp. 18-23, Aug. 2003. [3] M. Moeck, “Developments in digital addressable lighting control,” J. Light & Vis. Env., vol. 28, no. 2, pp. 104-106, Aug. 2004. [4] C. Gomez, and J. Paradells, “Wireless home automation networks: a survey of architectures and technologies,” IEEE Commum. Mag., vol. 48, no. 6, pp. 92-101, Jun 2010. IJPRES Volume II/Issue 1/JAN2014 [5] V. Chunduru, N. Subramanian, “Effects on power lines on performance of home control system,” Proc. Int. Conf. on Power Elec., Drives and Energy Systems (PEDES), Dec. 2006. [6] Lighting Research Center, Rensselaer Polytechnic Institute, “Reducing barriers to the use of highefficiency lighting systems,” Feb. 2002. [7] M. Aliberti, “Green networking in home and building automation systems through power state switching,” IEEE Trans. Consumer Electron., vol. 57, no. 2, pp. 445-452 May 2011. [8] D. Lechner, W. Granzer, and W. Kastner, “Security for KNXnet/IP,” Konnex Scientific Conf., Nov. 2008. [9] W. S. Lee, S. H. Hong, “Implementation of a KNX-ZigBee gateway for home automation,” 13th IEEE Int. Symp. on Consumer Electron. (ISCE), pp. 545-549, May 2009. [10] F. Ferreira, A. L. Osorio, J. M. F. Calado, and C. S. Pedro, “Building automation interoperability – A review,” 17th Int. Conf. on Systems, Signals and Image Process (IWSSIP), Jun. 2010. [11] Y. Ma, and D. Wobschall, “A sensor network for buildings based on the DALI bus,” IEEE Sensors Applic. Symp. (SAS), Feb. 2007. [12] K. Gill, S. H. Yang, F. Yao, and X. Lu, “A ZigBee-based home automation system,” IEEE Trans. Consumer Electron., vol. 55, no. 2, pp. 422-430, May 2009. [13] D. M. Han, and J. H. Lim, “Smart home energy management system using IEEE 802.15.4 and ZigBee,” IEEE Trans. Consumer Electron., vol. 56, no. 3, pp. 1403-1410, Aug. 2010. [14] D. M. Han, and J. H. Lim, “Design and implementation of smart home energy management systems based on ZigBee,” IEEE Trans. Consumer Electron., vol. 56, no. 3, pp. 1417-1425, Aug. 2010. [15] C. Buratti, A. Conti, D. Dardari, and R. Verdone, “An overview on wireless sensor networks technology and evolution,” Sensors, vol. 9, no.9, pp. 6869-6896, Sep 2009. [16] F. J. Bellido-Outeirino, J. M. Flores-Arias, F. Domingo-Perez, A. Gil-de- Castro and A. MorenoMunoz, “In-Building Lighting Management System with Wireless Communications”, Proc. International Conference on Consumer Electronics ICCE Las Vegas, January 2012. [17] F. Domingo-Perez, A. Gil-de-Castro, J. M. Flores-Arias, F. J. Bellido- Outeirino, and A. Moreno-Munoz, “Low-rate wireless personal area networks applied to street lighting,” Lighting Res. & Techn., prepublished Dec. 14, 2011, DOI: 10.1177/1477153511431129. [18] D. Dietrich, D. Bruckner, G. Zucker, and P. Palensky, “Communication and computation in buildings: a short introduction and overview”, IEEE 16 INTERNATIONAL JOURNAL OF PROFESSIONAL ENGINEERING STUDIES Volume II/Issue 1/JAN2014 Trans. Ind. Electron., vol. 57, no. 11, pp. 3577-3584, Nov. 2010. V.SIVAPARVATHI, pursuing her M.tech in Embedded Systems from Nova College of Engineering & Technology for Women, Jupudi villaga, Ibrahimpatnam mandal, Krishna Dist, A.P, India. Affiliated to Jawaharlal Nehru Technological University, Kakinada, and is approved by AICTE Delhi. P.SUDHAKAR RAO, his Qualification is M.tech, currently working as an Associate Professor, in the Department of Electronics and communication Engineering, Nova College of Engineering & Technology for Women, Jupudi village, Ibrahimpatnam mandal, Krishna Dist, A.P, India. Affiliated to Jawaharlal Nehru Technological University, Kakinada, and is approved by AICTE Delhi. IJPRES 17
