Modeling of Photovoltaic Cell Using Free Software Application for Training and Design Circuit in Photovoltaic Solar Energy

There are numerous studies that develop the mathematical modeling of photovoltaic cells and verified by software. The model presented is based on an equivalent circuit implemented in free software. Free software used is Quite Universal Circuit Simulator (QUCS). QUCS uses a generic diode for adjust the current and voltage curve (IVcurve) at photovoltaic cell. Additionally, you can use equations to define the model of photovoltaic cell and represent the characteristic curves on the same page. QUCS is a multiplatform application that runs on Windows and Linux, this software is available in Linux distributions for electronics. Using QUCS to model a PV cell allows subcircuit and a real representation to a attractive presentation for teaching. In section 5 show examples of practices used on formation, further can be used on: courses of photovoltaic, online formation or distance learning, because only need download QUCS application, and is a good complement to a previous works on labo¿ ratory or concepts review for theory. Advantage to used QUCS is that allow several PV cells with a few mouse click, also does not needs buy additional PV cells to used on laboratory because can be modelled the PV cell available on laboratory. Further, is not a problem the availability material on laboratory, because the material of PV system can be expensive, then is best provide a good photovoltaic devices that a devices for all student in a class.Pareja Aparicio, M.; Pelegrí Sebastiá, J.; Sogorb Devesa, TC.; Llario Sanjuan, JV. (2013). Modeling of Photovoltaic Cell Using Free Software Application for Training and Design Circuit in Photovoltaic Solar Energy. En New Developments in Renewable Energy. InTech. 121-139. doi:10.5772/51925S12113

A Dual-Band Antenna for RF Energy Harvesting Systems in Wireless Sensor Networks

In this paper, we focus on ambient radio frequency energy available from commercial broadcasting stations in order to provide a system based on RF energy harvesting using a new design of receiving antenna. Several antenna designs have been proposed for use in RF energy harvesting systems, as a pertinent receiving antenna design is highly required since the antenna features can affect the amount of energy harvested. The proposed antenna is aimed at greatly increasing the energy harvesting efficiency over Wi-Fi bands: 2.45GHz and 5GHz. This provides a promising alternative energy source in order to power sensors located in harsh environments or remote places, where other energy sources are impracticable.The dual-band antenna can be easily integrated with RF energy harvesting system on the same circuit board. Simulations and measurements were carried out to evaluate the antenna performances and investigate the effects of different design parameters on the antenna performance.The receiving antenna meets the required bandwidth specification and provides peak gain of more than 4 dBi across the operating band.This work was supported in part by EMMAG Program 2014. The tests have been performed under the collaboration with the Electromagnetic Radiation Laboratory (GRE Lab) of the UPV.Bakkali, A.; Pelegrí Sebastiá, J.; Sogorb Devesa, TC.; Llario Sanjuan, JV.; Bou Escrivà, A. (2016). A Dual-Band Antenna for RF Energy Harvesting Systems in Wireless Sensor Networks. Journal of Sensors. 2016:1-8. doi:10.1155/2016/5725836S182016Sudevalayam, S., & Kulkarni, P. (2011). Energy Harvesting Sensor Nodes: Survey and Implications. IEEE Communications Surveys & Tutorials, 13(3), 443-461. doi:10.1109/surv.2011.060710.00094Bottner, H., Nurnus, J., Gavrikov, A., Kuhner, G., Jagle, M., Kunzel, C., … Schlereth, K.-H. (2004). New thermoelectric components using microsystem technologies. Journal of Microelectromechanical Systems, 13(3), 414-420. doi:10.1109/jmems.2004.828740Hande, A., Polk, T., Walker, W., & Bhatia, D. (2007). Indoor solar energy harvesting for sensor network router nodes. Microprocessors and Microsystems, 31(6), 420-432. doi:10.1016/j.micpro.2007.02.006Alippi, C., & Galperti, C. (2008). An Adaptive System for Optimal Solar Energy Harvesting in Wireless Sensor Network Nodes. IEEE Transactions on Circuits and Systems I: Regular Papers, 55(6), 1742-1750. doi:10.1109/tcsi.2008.922023Mikeka, C., & Arai, H. (2011). Design Issues in Radio Frequency Energy Harvesting System. Sustainable Energy Harvesting Technologies - Past, Present and Future. doi:10.5772/25348Nintanavongsa, P., Muncuk, U., Lewis, D. R., & Chowdhury, K. R. (2012). Design Optimization and Implementation for RF Energy Harvesting Circuits. IEEE Journal on Emerging and Selected Topics in Circuits and Systems, 2(1), 24-33. doi:10.1109/jetcas.2012.2187106Vyas, R. J., Cook, B. B., Kawahara, Y., & Tentzeris, M. M. (2013). E-WEHP: A Batteryless Embedded Sensor-Platform Wirelessly Powered From Ambient Digital-TV Signals. IEEE Transactions on Microwave Theory and Techniques, 61(6), 2491-2505. doi:10.1109/tmtt.2013.2258168Farinholt, K. M., Park, G., & Farrar, C. R. (2009). RF Energy Transmission for a Low-Power Wireless Impedance Sensor Node. IEEE Sensors Journal, 9(7), 793-800. doi:10.1109/jsen.2009.2022536Md. Din, N., Chakrabarty, C. K., Bin Ismail, A., Devi, K. K. A., & Chen, W.-Y. (2012). DESIGN OF RF ENERGY HARVESTING SYSTEM FOR ENERGIZING LOW POWER DEVICES. Progress In Electromagnetics Research, 132, 49-69. doi:10.2528/pier1207200