Eemeli työpaja nro 12, Micronova Research in Nanotechnologies and Sensing Tapani Ryhänen Nokia Research Center, Sensor and Material Technologies Laboratory (Cambridge, Otaniemi, Skolkovo) November 12, 2012 1
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MEMS and CMOS sensors in mass volumes Low cost, small size sensors with low power consumption and sophisticated electronics are now available in large volumes Moore s law (CMOS and MEMS) made this happen in ten years (~ 1995 ~ 2005) - but not without specific effort Angular rate Pressure Magnetometer Silicon microphone Miniaturization of packaged 3 axis silicon accelerometers (STMicroelectronics); 2002-2005 Accelerometer MEMS Game controllers and activity monitor prototypes and pilot products by Nokia Research Center; 2003-2004 3
Nokia as a pioneer in mobile MEMS sensors Accelerometer MMC card 2003 Fitness finder 2004 Digital compass 2003 N95 2007 Source: Yole Developpement 4
Multipurpose Touch Panels Strain Touch sensors on the surface of the display and other structural parts of a mobile device can be used as a platform of sensors and actuators. Touch sensors detecting hovering Deformation sensors (e.g. bending) Detection of forces applied on the device (e.g. control by squeezing, grip detection) Integration of vibrotactile and/or electrotactile actuators Integration of other sensors (e.g. temperature, skin impedance) Pressure Proximity Multifunctional Capacitive Sensor for Stretchable Multipurpose Touch Panel (Nokia Research Center UK and University of Cambridge) Kinetic interaction with mobile device based on multifunctional touch panel sensors responsive to the deformation of the device body (Nokia Research Center Finland and UK) 5
New Platforms for Sensor Integration Flexible and Stretchable Electronics Graphene electronics and self-assembled polymer and inorganic nanostructures Sensing device prototypes Intelligent algorithms, machine learning and new measurement principles 6 Large scale, low cost manufacturing by roll-to-roll processes
Sensors in Mobile Devices First wave: MEMS sensors and touch panels (2002 2012) Silicon accelerometers became available based on mass production processes for automotive industry; smaller package, lower supply voltages, less power Capacitive touch sensors as a mass volume enabler of mobile device user interfaces Key drivers: adaptive user interface, touch displays, application development Smart sensor modules and sensor fusion for consumer products (2013 ) Integration of MEMS sensors into smart sensor modules (inertial combos with signal processing and embedded algorithms) Basic motion and gesture recognition algorithms as an integral part of smart sensors Key drivers: contextual intelligence, adaptive UI, application specific devices New materials and intelligent algorithms enable more sensing (2015 ) New materials, such as graphene, enable arrays of chemical and environmental sensors with high level of integration (energy, sensors, analog electronics) Machine learning methods enable intelligent, adaptive, learning, predictive sensors Key drivers: Big Data, Internet-of-Things, pervasiveness of sensors 7
Research in Form Factors Flexible Devices Intelligent Devices Wearable Devices User experience driven research on flexible mobile products Technology portfolio and manufacturing solutions for flexible products Ultimate outdoors, sports, health, fitness, wellness experiences Life-logging of personal sensor data and related data analytics Wearable devices: near-eye-display, headsets, wearable cameras, wrist devices Wearable multimedia and augmented reality based on optimized wearable devices 8
Morph Transformable, Transparent 2007 A concept device introduced in 2008 in MoMA, New York; in London Science Museum 2009 Ultra thin, transformable, partly transparent device based on stretchable electronics research 9 reddot best of the best award 2008 UK Trade and Investment Nordic Innovation Award 2010 FinNano Award 2010 Over 5 million views in YouTube
Nokia Kinetic Device 2010 Demonstrator of kinetic user interface concepts shown in Nokia World 2011 What the heck Nokia s crazy kinetic device is real : roughly 150000 Google hits and over 1 million views in YouTube within the 5 first days 10
Wearable Haptic feedback Flexible and bendable Light and robust 11 Transformable, stretchable, foldable Large screen Transparent
What is needed to build a flexible product Integrated flexible sensors; e-skin Advanced antenna construction Flexible, shearing OCA Flexible, robust display Strain-limiting casing Flexible capacitive touch panel Hard wearing, deep-colour, flexible casing materials with feel of quality Flexible, conformable RF shielding Stress-relieving film to protect display and ensure smooth bending Flexible energy storage Flexible, thin, robust motherboard 12
Graphene Radical technology = Significantly higher performance over the state-of-art Generic technology = Wide range of potential applications Disruptive technology = It offers new value propositions GRAPHENE S SUPERLATIVES ü Thinnest imaginable material ü Largest surface area (2700 m^2 per g) ü Strongest material ever measures (theoretical limit) ü Stiffest known material ü Most stretchable crystal (up to 20 % elastically) ü Record thermal conductivity (outperforming diamond) ü Highest current density at RT (10^6 times of Cu) ü Compete impermeable (even for He atoms) ü Highest intrinsic mobility (100 times more than Si) ü Conducts electricity in the limit NO electrons ü Lightest charge carriers (zero rest mass) ü Longest mean free path at room T (µm scale) 13
Horizontal Platform, Vertical Integration Graphene is a versatile material that will be used to improve the performance of various electrical components and/or to create new components Ø Supporting existing value chains and developing horizontal technologies Graphene can be an enabler for new manufacturing paradigms (printing, R2R) that integrate different components into integrated functional systems Ø Disrupting existing value chains and creating vertically integrated novel products Materials Versatile functional material Components Integrated functional systems For example, sensors, signal processing, communication, and energy End products End products 14
Technology Differentiation and Disruptions in Manufacturing Europe can compete by radically differentiating technologies Europe can t compete by minimizing costs of traditional technologies. Europe can compete by providing truly disruptive manufacturing solutions not by incremental development steps for existing manufacturing capabilities. 15
Thank You 16