A printed proximity-sensing surface based on organic pyroelectric sensors and organic thin-film transistor electronics

Marco Fattori; Simone Cardarelli; Joost Fijn; Pieter Harpe; Micael Charbonneau; Denis Locatelli; Stephanie Lombard; Christelle Laugier; Laurent Tournon; Stephanie Jacob; Krunoslav Romanjek; Romain Coppard; Herbert Gold; Manfred Adler; Martin Zirkl; Jonas Groten; Andreas Tschepp; Bernhard Lamprecht; Markus Postl; Barbara Stadlober; Josephine Socratous; Eugenio Cantatore

doi:10.1038/s41928-022-00762-6

A printed proximity-sensing surface based on organic pyroelectric sensors and organic thin-film transistor electronics

Marco Fattori (Corresponding author), Simone Cardarelli, Joost Fijn, Pieter Harpe, Micael Charbonneau, Denis Locatelli, Stephanie Lombard, Christelle Laugier, Laurent Tournon, Stephanie Jacob, Krunoslav Romanjek, Romain Coppard, Herbert Gold, Manfred Adler, Martin Zirkl, Jonas Groten, Andreas Tschepp, Bernhard Lamprecht, Markus Postl, Barbara StadloberJosephine Socratous, Eugenio Cantatore

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Large-area, flexible proximity-sensing surfaces are useful in a range of applications including process control, work security and robotics. However, current systems typically require rigid and thick electronics, which limit how they can be used. Here we report a flexible large-area proximity-sensing surface fabricated using printed organic materials and incorporating analogue front-end electronics in each pixel. The sensing surface is built with printed thin-film pyroelectric sensors based on poly(vinylidene fluoride-co-trifluoroethylene) co-polymers and printed organic thin-film transistors. A 5 × 10 matrix frontplane, consisting of long-wavelength infrared organic pyroelectric sensors, is laminated with an organic transistor analogue front-end backplane. The electronic front end provides sensor-signal amplification and pixel addressing to maximize the detection distance and reduce pixel crosstalk. An average yield of 82% fully working pixels for the backplane and a maximum system yield of 96%, which corresponds to 768 defect-free devices, are achieved. The system can detect a human hand approaching from different directions and track the position of a movable heat source up to a distance of around 0.4 m at a readout speed of 100 frames per second.

Original language	English
Pages (from-to)	289-299
Number of pages	11
Journal	Nature Electronics
Volume	5
Issue number	5
DOIs	https://doi.org/10.1038/s41928-022-00762-6
Publication status	Published - May 2022

Bibliographical note

Funding Information:
We would like to acknowledge financial support from the European Commission for the projects ATLASS (Horizon 2020, Nanotechnologies, Advanced Material and Production theme, contract no. 636130, to M.F., J.F., E.C., M.C., D.L., S.L., C.L., L.T., S.J, K.R., R.C., H.G., M.A., M.Z., J.G., A.T., M.P., B.L., B.S. and J.S.).

Funding

We would like to acknowledge financial support from the European Commission for the projects ATLASS (Horizon 2020, Nanotechnologies, Advanced Material and Production theme, contract no. 636130, to M.F., J.F., E.C., M.C., D.L., S.L., C.L., L.T., S.J, K.R., R.C., H.G., M.A., M.Z., J.G., A.T., M.P., B.L., B.S. and J.S.).

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Cite this

Fattori, M., Cardarelli, S., Fijn, J., Harpe, P., Charbonneau, M., Locatelli, D., Lombard, S., Laugier, C., Tournon, L., Jacob, S., Romanjek, K., Coppard, R., Gold, H., Adler, M., Zirkl, M., Groten, J., Tschepp, A., Lamprecht, B., Postl, M., ... Cantatore, E. (2022). A printed proximity-sensing surface based on organic pyroelectric sensors and organic thin-film transistor electronics. Nature Electronics, 5(5), 289-299. https://doi.org/10.1038/s41928-022-00762-6

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title = "A printed proximity-sensing surface based on organic pyroelectric sensors and organic thin-film transistor electronics",

abstract = "Large-area, flexible proximity-sensing surfaces are useful in a range of applications including process control, work security and robotics. However, current systems typically require rigid and thick electronics, which limit how they can be used. Here we report a flexible large-area proximity-sensing surface fabricated using printed organic materials and incorporating analogue front-end electronics in each pixel. The sensing surface is built with printed thin-film pyroelectric sensors based on poly(vinylidene fluoride-co-trifluoroethylene) co-polymers and printed organic thin-film transistors. A 5 × 10 matrix frontplane, consisting of long-wavelength infrared organic pyroelectric sensors, is laminated with an organic transistor analogue front-end backplane. The electronic front end provides sensor-signal amplification and pixel addressing to maximize the detection distance and reduce pixel crosstalk. An average yield of 82\% fully working pixels for the backplane and a maximum system yield of 96\%, which corresponds to 768 defect-free devices, are achieved. The system can detect a human hand approaching from different directions and track the position of a movable heat source up to a distance of around 0.4 m at a readout speed of 100 frames per second.",

author = "Marco Fattori and Simone Cardarelli and Joost Fijn and Pieter Harpe and Micael Charbonneau and Denis Locatelli and Stephanie Lombard and Christelle Laugier and Laurent Tournon and Stephanie Jacob and Krunoslav Romanjek and Romain Coppard and Herbert Gold and Manfred Adler and Martin Zirkl and Jonas Groten and Andreas Tschepp and Bernhard Lamprecht and Markus Postl and Barbara Stadlober and Josephine Socratous and Eugenio Cantatore",

note = "Funding Information: We would like to acknowledge financial support from the European Commission for the projects ATLASS (Horizon 2020, Nanotechnologies, Advanced Material and Production theme, contract no. 636130, to M.F., J.F., E.C., M.C., D.L., S.L., C.L., L.T., S.J, K.R., R.C., H.G., M.A., M.Z., J.G., A.T., M.P., B.L., B.S. and J.S.). ",

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Fattori, M , Cardarelli, S, Fijn, J, Harpe, P, Charbonneau, M, Locatelli, D, Lombard, S, Laugier, C, Tournon, L, Jacob, S, Romanjek, K, Coppard, R, Gold, H, Adler, M, Zirkl, M, Groten, J, Tschepp, A, Lamprecht, B, Postl, M, Stadlober, B, Socratous, J & Cantatore, E 2022, 'A printed proximity-sensing surface based on organic pyroelectric sensors and organic thin-film transistor electronics', Nature Electronics, vol. 5, no. 5, pp. 289-299. https://doi.org/10.1038/s41928-022-00762-6

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AU - Harpe, Pieter

AU - Charbonneau, Micael

AU - Locatelli, Denis

AU - Lombard, Stephanie

AU - Laugier, Christelle

AU - Tournon, Laurent

AU - Jacob, Stephanie

AU - Romanjek, Krunoslav

AU - Coppard, Romain

AU - Gold, Herbert

AU - Adler, Manfred

AU - Zirkl, Martin

AU - Groten, Jonas

AU - Tschepp, Andreas

AU - Lamprecht, Bernhard

AU - Postl, Markus

AU - Stadlober, Barbara

AU - Socratous, Josephine

AU - Cantatore, Eugenio

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N2 - Large-area, flexible proximity-sensing surfaces are useful in a range of applications including process control, work security and robotics. However, current systems typically require rigid and thick electronics, which limit how they can be used. Here we report a flexible large-area proximity-sensing surface fabricated using printed organic materials and incorporating analogue front-end electronics in each pixel. The sensing surface is built with printed thin-film pyroelectric sensors based on poly(vinylidene fluoride-co-trifluoroethylene) co-polymers and printed organic thin-film transistors. A 5 × 10 matrix frontplane, consisting of long-wavelength infrared organic pyroelectric sensors, is laminated with an organic transistor analogue front-end backplane. The electronic front end provides sensor-signal amplification and pixel addressing to maximize the detection distance and reduce pixel crosstalk. An average yield of 82% fully working pixels for the backplane and a maximum system yield of 96%, which corresponds to 768 defect-free devices, are achieved. The system can detect a human hand approaching from different directions and track the position of a movable heat source up to a distance of around 0.4 m at a readout speed of 100 frames per second.

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A printed proximity-sensing surface based on organic pyroelectric sensors and organic thin-film transistor electronics

Abstract

Bibliographical note

Funding

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Proximity Heat Sensors on Robots Could Minimize Hazards in Human-Robot Interaction in Industry

New printing method for artificial "skin" containing heat sensors

Cite this

A printed proximity-sensing surface based on organic pyroelectric sensors and organic thin-film transistor electronics

Abstract

Bibliographical note

Funding

Access to Document

Other files and links

Fingerprint

Press/Media

Proximity Heat Sensors on Robots Could Minimize Hazards in Human-Robot Interaction in Industry

New printing method for artificial "skin" containing heat sensors

Cite this