Man-machine communication - A transparent switchboard for computers

Device uses pattern of transparent contact touch points that are put on cathode ray tube screen. Touch point system compels more precise and unambiguous communication between man and machine than is possible with any other means, and speeds up operation responses

Transparent switchboard

A tin oxide coating is formed on a plate of glass and the coating is then etched away from the glass in thin lines to form separate electrical conductors which extend to one end of the plate and connect to either a vertical (column) or horizontal (row) position sensing SCR circuit. A thin transparent insulating coating is formed over the oxide layer except at selected touch points which are positioned in a matrix pattern of vertical columns and horizontal rows. Touching one of these points with a finger bridges the thin line between adjacent conductors to activate trigger circuits in the particular row and column sensing circuits associated with the point touched. The row and column sensing circuits are similar and are powered with a low frequency, ac voltage source. The source for the row circuits is 180 out of phase with the source for the column circuits so that one circuit acts as ground for the other during half of the supply voltage cycle. The signals from the sensing circuits are input to a logic circuit which determines the presence of a valid touch, stores a binary matrix number associated with the touched point, signals a computer of the presence of a stored number and prevents storage of a new number before receiving an enable signal from the computer

Fast and stable gratings inscription in POFs made of different materials with pulsed 248 nm KrF laser

"© 2018 Optical Society of America. One print or electronic copy may be made for personal use only. Systematic reproduction and distribution, duplication of any material in this paper for a fee or for commercial purposes, or modifications of the content of this paper are prohibited"[EN] This paper presents fiber Bragg grating (FBG) inscription with a pulsed 248 nm UV KrF laser in polymer optical fibers (POFs) made of different polymers, namely polymethyl methacrylate (PMMA), cyclic-olefin polymer and co-polymer, and Polycarbonate. The inscribed gratings and the corresponding inscription parameters are compared with grating inscribed in POFs made of the aforementioned materials but with the hitherto most used laser for inscription, which is a continuous wave 325 nm UV HeCd laser. Results show a reduction of the inscription time of at least 16 times. The maximum time reduction is more than 130 times. In addition, a reflectivity and a bandwidth close to or higher than the ones with the 325 nm laser were obtained. The polymer optical fiber Bragg gratings (POFBGs) inscribed with the 248 nm laser setup present high stability with small variations in their central wavelength, bandwidth, and reflectivity after 40 days. (c) 2018 Optical Society of America under the terms of the OSA Open Access Publishing Agreement.Fundacao para Ciencia e a Tecnologia (FCT) (SFRH/BPD/109458/2015, UID/EEA/50008/2013).Marques, C.; Min, R.; Leal-Junior, A.; Antunes, P.; Fasano, A.; Woyessa, G.; Nielsen, K.... (2018). Fast and stable gratings inscription in POFs made of different materials with pulsed 248 nm KrF laser. Optics Express. 26(2):2013-2022. https://doi.org/10.1364/OE.26.002013S20132022262Webb, D. J. (2015). Fibre Bragg grating sensors in polymer optical fibres. Measurement Science and Technology, 26(9), 092004. doi:10.1088/0957-0233/26/9/092004Prado, A. R., Leal-Junior, A. G., Marques, C., Leite, S., de Sena, G. L., Machado, L. C., … Pontes, M. J. (2017). Polymethyl methacrylate (PMMA) recycling for the production of optical fiber sensor systems. Optics Express, 25(24), 30051. doi:10.1364/oe.25.030051Hu, X., Saez-Rodriguez, D., Marques, C., Bang, O., Webb, D. J., Mégret, P., & Caucheteur, C. (2015). Polarization effects in polymer FBGs: study and use for transverse force sensing. Optics Express, 23(4), 4581. doi:10.1364/oe.23.004581Pospori, A., Marques, C. A. F., Bang, O., Webb, D. J., & André, P. (2017). Polymer optical fiber Bragg grating inscription with a single UV laser pulse. Optics Express, 25(8), 9028. doi:10.1364/oe.25.009028Marques, C. A. F., Webb, D. J., & Andre, P. (2017). Polymer optical fiber sensors in human life safety. Optical Fiber Technology, 36, 144-154. doi:10.1016/j.yofte.2017.03.010Fasano, A., Woyessa, G., Janting, J., Rasmussen, H. K., & Bang, O. (2017). Solution-Mediated Annealing of Polymer Optical Fiber Bragg Gratings at Room Temperature. IEEE Photonics Technology Letters, 29(8), 687-690. doi:10.1109/lpt.2017.2678481Woyessa, G., Pedersen, J. K. M., Fasano, A., Nielsen, K., Markos, C., Rasmussen, H. K., & Bang, O. (2017). Zeonex-PMMA microstructured polymer optical FBGs for simultaneous humidity and temperature sensing. Optics Letters, 42(6), 1161. doi:10.1364/ol.42.001161Fasano, A., Woyessa, G., Stajanca, P., Markos, C., Stefani, A., Nielsen, K., … Bang, O. (2016). Fabrication and characterization of polycarbonate microstructured polymer optical fibers for high-temperature-resistant fiber Bragg grating strain sensors. Optical Materials Express, 6(2), 649. doi:10.1364/ome.6.000649Woyessa, G., Nielsen, K., Stefani, A., Markos, C., & Bang, O. (2016). Temperature insensitive hysteresis free highly sensitive polymer optical fiber Bragg grating humidity sensor. Optics Express, 24(2), 1206. doi:10.1364/oe.24.001206Leal-Junior, A. G., Frizera, A., & José Pontes, M. (2018). Sensitive zone parameters and curvature radius evaluation for polymer optical fiber curvature sensors. Optics & Laser Technology, 100, 272-281. doi:10.1016/j.optlastec.2017.10.006Stefani, A., Andresen, S., Yuan, W., Herholdt-Rasmussen, N., & Bang, O. (2012). High Sensitivity Polymer Optical Fiber-Bragg-Grating-Based Accelerometer. IEEE Photonics Technology Letters, 24(9), 763-765. doi:10.1109/lpt.2012.2188024Marques, C. A. F., Peng, G.-D., & Webb, D. J. (2015). Highly sensitive liquid level monitoring system utilizing polymer fiber Bragg gratings. Optics Express, 23(5), 6058. doi:10.1364/oe.23.006058Jensen, J. B., Hoiby, P. E., Emiliyanov, G., Bang, O., Pedersen, L. H., & Bjarklev, A. (2005). Selective detection of antibodies in microstructured polymer optical fibers. Optics Express, 13(15), 5883. doi:10.1364/opex.13.005883Emiliyanov, G., Høiby, P., Pedersen, L., & Bang, O. (2013). Selective Serial Multi-Antibody Biosensing with TOPAS Microstructured Polymer Optical Fibers. Sensors, 13(3), 3242-3251. doi:10.3390/s130303242Hassan, H. U., Janting, J., Aasmul, S., & Bang, O. (2016). Polymer Optical Fiber Compound Parabolic Concentrator fiber tip based glucose sensor: in-Vitro Testing. IEEE Sensors Journal, 1-1. doi:10.1109/jsen.2016.2606580Yuan, W., Khan, L., Webb, D. J., Kalli, K., Rasmussen, H. K., Stefani, A., & Bang, O. (2011). Humidity insensitive TOPAS polymer fiber Bragg grating sensor. Optics Express, 19(20), 19731. doi:10.1364/oe.19.019731Johnson, I. P., Yuan, W., Stefani, A., Nielsen, K., Rasmussen, H. K., Khan, L., … Bang, O. (2011). Optical fibre Bragg grating recorded in TOPAS cyclic olefin copolymer. Electronics Letters, 47(4), 271. doi:10.1049/el.2010.7347Markos, C., Stefani, A., Nielsen, K., Rasmussen, H. K., Yuan, W., & Bang, O. (2013). High-T_g TOPAS microstructured polymer optical fiber for fiber Bragg grating strain sensing at 110 degrees. Optics Express, 21(4), 4758. doi:10.1364/oe.21.004758Woyessa, G., Fasano, A., Stefani, A., Markos, C., Nielsen, K., Rasmussen, H. K., & Bang, O. (2016). Single mode step-index polymer optical fiber for humidity insensitive high temperature fiber Bragg grating sensors. Optics Express, 24(2), 1253. doi:10.1364/oe.24.001253Woyessa, G., Fasano, A., Markos, C., Stefani, A., Rasmussen, H. K., & Bang, O. (2016). Zeonex microstructured polymer optical fiber: fabrication friendly fibers for high temperature and humidity insensitive Bragg grating sensing. Optical Materials Express, 7(1), 286. doi:10.1364/ome.7.000286Stefani, A., Nielsen, K., Rasmussen, H. K., & Bang, O. (2012). Cleaving of TOPAS and PMMA microstructured polymer optical fibers: Core-shift and statistical quality optimization. Optics Communications, 285(7), 1825-1833. doi:10.1016/j.optcom.2011.12.033Nielsen, K., Rasmussen, H. K., Adam, A. J., Planken, P. C., Bang, O., & Jepsen, P. U. (2009). Bendable, low-loss Topas fibers for the terahertz frequency range. Optics Express, 17(10), 8592. doi:10.1364/oe.17.008592Nielsen, K., Rasmussen, H. K., Jepsen, P. U., & Bang, O. (2010). Broadband terahertz fiber directional coupler. Optics Letters, 35(17), 2879. doi:10.1364/ol.35.002879Anthony, J., Leonhardt, R., Argyros, A., & Large, M. C. J. (2011). Characterization of a microstructured Zeonex terahertz fiber. Journal of the Optical Society of America B, 28(5), 1013. doi:10.1364/josab.28.001013Woyessa, G., Fasano, A., Markos, C., Rasmussen, H. K., & Bang, O. (2017). Low Loss Polycarbonate Polymer Optical Fiber for High Temperature FBG Humidity Sensing. IEEE Photonics Technology Letters, 29(7), 575-578. doi:10.1109/lpt.2017.2668524Johnson, I. P., Kalli, K., & Webb, D. J. (2010). 827 nm Bragg grating sensor in multimode microstructured polymer optical fibre. Electronics Letters, 46(17), 1217. doi:10.1049/el.2010.1595Stefani, A., Wu Yuan, Markos, C., & Bang, O. (2011). Narrow Bandwidth 850-nm Fiber Bragg Gratings in Few-Mode Polymer Optical Fibers. IEEE Photonics Technology Letters, 23(10), 660-662. doi:10.1109/lpt.2011.2125786Hu, X., Pun, C.-F. J., Tam, H.-Y., Mégret, P., & Caucheteur, C. (2014). Highly reflective Bragg gratings in slightly etched step-index polymer optical fiber. Optics Express, 22(15), 18807. doi:10.1364/oe.22.018807Hu, X., Pun, C.-F. J., Tam, H.-Y., Mégret, P., & Caucheteur, C. (2014). Tilted Bragg gratings in step-index polymer optical fiber. Optics Letters, 39(24), 6835. doi:10.1364/ol.39.006835Sáez-Rodríguez, D., Nielsen, K., Rasmussen, H. K., Bang, O., & Webb, D. J. (2013). Highly photosensitive polymethyl methacrylate microstructured polymer optical fiber with doped core. Optics Letters, 38(19), 3769. doi:10.1364/ol.38.003769Hu, X., Woyessa, G., Kinet, D., Janting, J., Nielsen, K., Bang, O., & Caucheteur, C. (2017). BDK-doped core microstructured PMMA optical fiber for effective Bragg grating photo-inscription. Optics Letters, 42(11), 2209. doi:10.1364/ol.42.002209Statkiewicz-Barabach, G., Kowal, D., Mergo, P., & Urbanczyk, W. (2015). Comparison of growth dynamics and temporal stability of Bragg gratings written in polymer fibers of different types. Journal of Optics, 17(8), 085606. doi:10.1088/2040-8978/17/8/085606Marques, C., Pospori, A., Demirci, G., Çetinkaya, O., Gawdzik, B., Antunes, P., … Webb, D. (2017). Fast Bragg Grating Inscription in PMMA Polymer Optical Fibres: Impact of Thermal Pre-Treatment of Preforms. Sensors, 17(4), 891. doi:10.3390/s17040891Bundalo, I.-L., Nielsen, K., Markos, C., & Bang, O. (2014). Bragg grating writing in PMMA microstructured polymer optical fibers in less than 7 minutes. Optics Express, 22(5), 5270. doi:10.1364/oe.22.005270Oliveira, R., Bilro, L., & Nogueira, R. (2015). Bragg gratings in a few mode microstructured polymer optical fiber in less than 30 seconds. 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Optical Materials Express, 7(3), 967. doi:10.1364/ome.7.00096

Revenue Management: A Real Options Approach

Revenue management is the process of actively managing inventory or capacity to maximize revenues. The active management typically occurs through managerial levers such as price, promotion, or availability. We present a novel real options approach to revenue management that is specifically suited to the car rental business. We illustrate the concept with actual car rental data. The model produces minimally acceptable prices and inventory release quantities (number of cars available for rent at a given price) as a function of remaining time and available inventory. The pricing and inventory release recommendations of the developed model confirm earlier empirical analysis that suggested current practices discount too deeply early in the booking cycle

Electrohydrodynamic instability of two superposed fluids in normal electric fields

AbstractWe consider the linear stability of two unbounded fluids that are separated by a plane interface, and stressed by initially perpendicular uniform electric field. On each side of the interface there is a Coquette flow. The fluids have different viscosities, densities, and electrical properties and surface tension acts at the interface. The linear stability of the flow is analyzed by deriving the exact dispersion relation in terms of the Airy functions and their integrals, and solving it numerically and asymptotically to find marginal stability curves. The stability of the system depends on ten parameters: the ratio of viscosities, ratio of the densities, surface tension, gravity, ratio of the permitivities, two conductivities, two equilibrium electric fields and velocity of the upper fluid in the unperturbed motion. We investigate the electric charge relaxation effects on the stability of the flow by considering various limiting cases. We also examine the effects of finite charge relaxation times

Stochastic Analysis of Synchronization in a Supermarket Refrigeration System

Display cases in supermarket systems often exhibit synchronization, in which the expansion valves in the display cases turn on and off at exactly the same time. The study of the influence of switching noise on synchronization in supermarket refrigeration systems is the subject matter of this work. For this purpose, we model it as a hybrid system, for which synchronization corresponds to a periodic trajectory. Subsequently, we investigate the influence of switching noise. We develop a statistical method for computing an intensity function, which measures how often the refrigeration system stays synchronized. By analyzing the intensity, we conclude that the increase in measurement uncertainty yields the decrease at the prevalence of synchronization.Comment: In Proceedings HAS 2014, arXiv:1501.0540