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EETE JULAUG 2013

FLEXIBLE ELECTRONICS Printed electronics opens up large flexible sensor design opportunities By Laurent Jamet Compared to traditional electronic solutions, printed electronics offers several differentiating factors which make them particularly well suited to sensing application. Most printing processes are compatible with large area substrates, which enable the design of large area sensors with sensing capabilities across surfaces of up to 500x500mm. This at a very competitive cost per area ratio (compared to amorphous silicon or CMOS technologies). A pioneer in printed electronics applied to optical sensors, Isorg addresses several markets and functionalities. This includes scanning surfaces for X-ray digital imaging with the co-integration of organic photodiodes with transistors on amorphous silicon, fully integrated in printed electronics with organic photodiodes combined with organic transistors on plastic substrate. In the future, substituting amorphous silicon technology with organic electronics will increase cost competitiveness and enable new products developments (for lighter and more robust portable equipment). The first demonstrator of such a full organic Fig. 1: Plastic image sensor prototype (Isorg / Plastic Logic) image sensor is being fabricated as a collaborative development between Isorg and Plastic Logic. More particularly, the collaboration focuses on the deposition of organic printed photodetectors onto a plastic organic thin-film transistor backplane, to create a flexible sensor with a 40x40mm active area, 375um pitch (175um pixel size with 200um spacing) and a 94x95 = 8 930 pixel resolution – see figure 1. Biometrics applications using fingerprint and palmar surface recognition could use printed electronics to substitute the typical CMOS-based sensors with thinner and lighter organic solutions. Current developments yield a pixel resolution of 50um. Such approaches could also enable the design of large scanning surfaces to substitute CCD line scanners in office equipment, yielding faster, lighter and thinner document scanners. So far in this field, a pixel resolution of 80um has been achieved for a 300 dpi document scanning resolution. Printed electronics also finds its way in temperature sensors in printed electronics (figure 2), applying its large area sensing capabilities to the detection of hot spots, for example to monitor the power distribution and heat dissipation in power electronics circuit boards. Thin and flexible: a system-on-foil approach Using PET as a substrate, it is now possible to design systemon foil sensing solutions that combine optical sensors, discrete components such LED and flexible interconnections. In this way, contactless user interfaces can be built using organic photodetectors, offering functionalities such as hand proximity detection and gesture recognition for power on/off or linear control (slider and vertical distance detection). These conformable system-on-foil user interfaces can even be integrated in smart textiles products. The optical solution relies on the detection by organic photodetectors of the reflected infra-red light emitted by IR-LEDs directly mounted on a flex circuit, as shown in figure 3. For this purpose, the organic semiconductor materials can be tuned to operate both in visible and near infra-red bands. Being very thin and easy to glue to other substrates such as paper, these new sensors can easily turn plastic and paper Laurent Jamet is co-founder and business development director of ISORG - www.isorg.fr - he can be reached at laurent.jamet@isorg.fr Fig. 2: Printed temperature sensor (Isorg). 34 Electronic Engineering Times Europe July/August 2013 www.electronics-eetimes.com


EETE JULAUG 2013
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