PHOSFOS: Difference between revisions

The PHOSFOS (Photonic Skins For Optical Sensing) project<ref>http://www.phosfos.eu/eng/Phosfos/About-us/Project-Summary </ref> is developing flexible and stretchable foils or skins that integrate optical sensing elements with optical and electrical devices as well as onboard signal processing and wireless communications, as seen in Figure 1. This flexible skins can be wrapped around, embedded in, attached and anchored to irregularly shaped and/or moving objects or bodies and will allow quasi-distributed sensing of mechanical quantities such as deformation, pressure, stress or strain.<ref>http://spie.org/x38859.xml?highlight=x2406&ArticleID=x38859</ref>. This approach potentially gives a significant advnatage over conventional sensing systems because of the portability of the resulting systems and the extended measurement range.

A summary of the key developments can be found on the PhoSFOS EU webpage [http://www.phosfos.eu/eng/Phosfos/Facts-Results] and include the demonstration of a fully flexible opto-electronic foil.<ref>Fully flexible opto-electronic foil, E. Bosman, G. Van Steenberge, I. Milenkov, K. Panajotov, H. Thienpont, J. Bauwelinck, P. Van Daele, Journal of Selected Topics in Quantum Electronics, 2010 </ref>.

Figure 3 shows the [[scattering]] of HeNe [[laser]] light from noise gratings recorded in [[PMMA]] using a 325 &nbsp;nm HeCd laser.

One of the early results from the project was the successful demonstration of a repeatable method of joining the polymer fiber to standard silica fibre. This was a major development and allowed for the first time POF Bragg gratings to be used in real applications outside of the optics lab. One of the first uses for these sensors was in monitoring the strain of tapestries<ref>http://eprints.soton.ac.uk/68650/01/137_Lennard.pdf</ref> shown in Figure 4,.<ref>http://spie.org/x39927.xml?ArticleID=x39927</ref>. In this case conventional electrical strain sensors and silica fiber sensors were shown to be strengthening the tapestries in areas where they were fixed. Because the polymer devices are much more flexible they do not distort the material as much and therefore give a much most accurate measurement of the strain in flexible materials. Temperature and humidity sensing using a combined silica / POF fiber sensor has been demonstrated.<ref>Optical fibre temperature and humidity sensor, C. Zhang, W. Zhang, D.J. Webb, G.D. Peng, Electronics Letters, 46, 9, pp643-644, 2010, {{doi|10.1049/el.2010.0879}} </ref>. Combined strain, temperature and bend sensing has also been shown.<ref>Bragg grating in polymer optical fibre for strain, bend and temperature sensing, X. Chen, C. Zhang, D.J Webb, G.-D. Peng , K. Kalli, Measurement Science and Technology, 2010 </ref>. Using a fiber Bragg grating in an eccentric core polymer has been shown to yield a high sensitivity to bend.<ref>Highly Sensitive Bend Sensor Based on Bragg Grating in Eccentric Core Polymer Fiber, X. Chen, C. Zhang, D.J. Webb, K. Kalli, G.-D. Peng, A. Argyros, IEEE Sensors Journal, 2010 </ref>.

Other recent progress includes the demonstration of birefringent photonic crystal fibers with zero polarimetric sensitivity to temperature,<ref>http://www.phosfos.eu/index.php/eng/Phosfos/Journals/Birefringent-photonic-crystal-fibers-with-zero-polarimetric-sensitivity-to-temperature</ref><ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results</ref>, and a successful demonstration of transversal load sensing with fibre Bragg gratings in microstructured optic fibers.<ref>http://www.phosfos.eu/index.php/eng/Phosfos/Journals/Transversal-Load-Sensing-with-Fiber-Bragg-Gratings-in-Microstructured-Optical-Fibers</ref>.

The key areas where significant progress has been made are listed below <ref> http://www.phosfos.eu/eng/Phosfos/Facts-Results </ref>:

1. '''Silica [[Microstructured fiber]]s for temperature insensitive optical sensors''' - a new pressure sensitive and temperature insensitive optical fibre sensor has been developed. The sensor uses a [[fiber Bragg grating]] written into a [[microstructured fiber]]. The pressure sensitivity exceeds the state-of-the-art with a factor of 20, whilst the sensor is truly temperature insensitive. The sensor is based on a novel design of a highly birefringent (10^-3−3) microstructured optical fibre sensor that is designed to have a high pressure sensitivity (3.3 pm/bar), whilst at the same time exhibit negligible temperature sensitivity (10^-2−2 pm/K). The fabrication method is compatible with conventional ultraviolet grating inscription setups for [[fiber Bragg grating]] manufacture. The temperature insensitivity was achieved by tailoring the design of the doped region in the core of the [[microstructured fiber]] via a series of design iterations.<ref> http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-sheet-01-Silica-Microstructured-Optical-Fibre-Sensor</ref>.

2. '''Embedded optoelectronic devices''' - the possibility to integrate optical sources and photodetectors, compatible with the optical fibre sensors has been developed within the PHOSFOS project. The optoelectronic components are thined down by polishing until they are only 20 μm thick so that they become flexible themselves without compromising functionality. Thin optical sources and detectors are then embedded in optical clear polymers, and electrically contacted using well-established micro- via, metallization and patterning technologies.<ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-02-Embedded-Opto-electronic-Chips</ref>.

3. '''Integrated sensors and optoelectronics''' - several different approaches for embedding optical fibre sensors in a flexible and stretchable host material, including injection molding, laser structuring, and soft lithography were considered. The influence of the embedding process was studied for silica and polymer [[fiber Bragg gratings]]. Temperature, humidity, strain, curvature and pressure sensitivities were fully characterized for different flexible host materials. An approach in which the embedded optoelectronic chips can be efficiently coupled towards the optical fiber sensors, using dedicated coupling structures, incorporating a 45˚ micromirror, as well as a fiber alignment groove was proposed. This allowed low cost components to be used in combination with well-established fabrication technologies, to demonstrate a truly low cost fully integrated sensing foil for biomedical applications.<ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-03-Integrating-Sensors-and-Opto-electronics-in-Flexible-Materials</ref>.

4. '''Polymer [[fiber Bragg gratings]]''' - Prior to the commencement of PHOSFOS, gratings in polymer optical fibre (POF) only existed in the 1550nm1550&nbsp;nm spectral region where the large fibre loss (1dB/cm) only permitted very short (<10cm10&nbsp;cm) fibre lengths to be used and the devices had to be butt-coupled to a silica fiber pigtail on the optical bench.

The PHOSFOS consortium has developed a means for reliably splicing POF to silica fibre and produced the first gratings in the 800nm800&nbsp;nm spectral region where losses are almost 2 orders of magnitude less than at 1550nm1550&nbsp;nm. These developments have allowed POF grating sensors to be used outside the laboratory for the first time.<ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-04-Polymer-Fibre-Bragg-Gratings</ref>.

5. '''Wavelength multiplexed polymer [[fiber Bragg gratings]]''' - once the fiber connection issue was solved it was possible to fabricated the first ever wavelength division multiplexed (WDM) Bragg grating sensors in polymer optical fibre (POF). Moreover by characterizing and using the thermal annealing properties of the fibre it was possible to shift the reflecting wavelength of a grating by over 20nm20&nbsp;nm, to enable multiple WDM sensors to be recorded with a single phase mask.

<ref> http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-05-Wavelength-Multiplexed </ref>

.<ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-06-Femtosecond-Fibre-Bragg-Grating-Fabrication</ref>.

7. '''Polymers for flexible skinlike materials''' - a series of polymer materials were developed that have inherent flexibility and tuneable mechanical strength. They are also visually transparent and are compatible with commercially available formulations. A great step forward in developing novel monomers and prepolymers that supplement commercial formulations was taken and several novel formulations created. Finally, we also developed a new [[optical fiber]] coating material that quickly cures on silica fibres under UV irradiation .<ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-07-Polymers-for-Flexible-Skinlike-Materials</ref>.

8. '''Sensing system for Silica [[Microstructured fiber]]s for pressure and temperature sensing''' - the silica MSF based pressure sensor has great potential value potential in the field of downhole pressure monitoring within the oil and gas industry. In this application there is a need to monitor high pressures (range from 0 to 1000 bar) in combination with fast temperature variations. The ultralow temperature cross-sensitivity is therefore an important feature of this system<ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-08-Silica-Microstructured-Optical-Fibre-Sensor-Pre-Product-Prototype </ref>

pressure sensing can be more challenging especially when space is limited. The PHOSFOS project consortium developed a new polymer multipoint FBG sensor that can measure the pressure in various medical applications. The fact that polymer fiber is used rather than silica fiber is beneficial in terms of patient safely. The low [[Young's modulus]] of polymer fiber improves the strain transfer from the surrounding medium to the sensors .<ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-09-Polymer-Fibre-Bragg-Grating-Oesophageal-Sensor-Demonstrator</ref> <ref>http://www.phosfos.eu/eng/Phosfos/Facts-Results/Fact-Sheet-10-Polymer-Fibre-Bragg-Grating-Interrogator </ref>.

The 2nd "Benefits for Industry" Meeting of the EU FP7 Project PHOSFOS will take place on Sunday 22nd22 May 2011 in Munich (Germany).

The meeting is co-located with the Industry Meets Academia Workshop organized by SPIE [[SPIE]] as part of the Optical Metrology Conference. It will be followed by the World of Photonics Congress and the Laser World of Photonics Trade Fair in Munich, in the week from 23rd23 to 26th26 May 2011.