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Nuestra Tecnología

Instrumentación para sensores ópticos

  1.  “Real-time optimal combination of multifrequency information in phase-resolved luminescence spectroscopy based on rectangular-wave signals". Sensors Actuators B 238 (2017) 221-225.

  2. “High performance optical oxygen sensors based on nanostructured films incorporating bichromophoric iridium complexes exhibiting interchromophore energy shuttling”. Analyst 141 (2016) 3090-3097.

  3. “Direct estimation of the standard error in phase-resolved luminescence measurements. Application to an oxygen measuring system”. Sensors Actuators B 224 (2016) 521-528.

  4. “Copper(I) complexes as alternatives to iridium(III) complexes for highly efficient oxygen sensing”. Chemical Communications 51 (2015) 11401-11404.

  5. "On the calibration of chemical sensors based on photoluminescence: Selecting the appropriate optimization criterion". Sensors Actuators B 212 (2015) 278-286.

  6. "Simple and flexible microfabrication of optical biosensing films using electrophoretic deposition". Austin Journal of Analytical and Pharmaceutical Chemistry 1 (2014) 4.

  7. "Improved multifrequency phase-modulation method that uses rectangular-wave signals to increase accuracy in luminescence spectroscopy". Analytical Chemistry 86 (2014) 5245-5256.

  8. "Electrophoretic deposition as a new approach to produce optical sensing films adaptable to microdevices". Nanoscale 6 (2014) 263-271.

  9. "Evaluation of a simple PC-based quadrature detection method at very low SNR for luminescence spectroscopy". Sensors Actuators B 192 (2014) 334-340.

  10. "High performance optical sensing nanocomposites for low and ultra-low oxygen concentrations using phase-shift measurements". Analyst 138 (2013) 4607-4617.

  11. "A new highly sensitive and versatile optical sensing film for controlling CO2 in gaseous and aqueous media". Sensors Actuators B 184 (2013) 281-287.

  12. "An open and low-cost optical-fiber measurement system for the optical detection of oxygen using a multifrequency phase-resolved method". Sensors Actuators B 176 (2013) 1110-1120.

  13. "In vitro oxygen sensing using intraocular microrobots". Transactions on Biomedical Engineering 59 (2012) 3104-3109. Front cover of the journal (link).

Sistemas de posicionamiento en interiores

  1.  "A synchronous TDMA ultrasonic TOF measurement system for low-power wireless sensor networks". IEEE Transactions on Instrumentation and Measurement, 62 (2013) 599-611.

  2. "Accurate time synchronization of ultrasonic TOF measurements in IEEE 802.15.4 based wireless sensor networks". Ad Hoc Networks 11 (2013) 442-452

  3. "Ultrasound indoor positioning system based on a low-power wireless sensor network providing sub-centimeter accuracy. Sensors 13 (2013) 3501-3501.

  4. "Feasibility of ultrasound positioning based on signal strength". IEEE International Conference on Indoor Positioning and Indoor Navigation (IPIN) (2012) 1-9.

  5. "TELIAMADE ultrasonic indoor location system: Application as a teaching tool". IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP) (2012) 2777-2780.