Papier Logik offers proven B2C and B2B Resources, products, technologies and know-how for many professionals from craftmen to engineers and product developers or else as partner and sub-contractor for Startup and new products development.
We have been distributing functional papers and multiple outcomes since 2007 and we are currently able to produce these raw materials and their applications through experienced expert manufacturers from Europe or North America.
Paper-Based Force-Sensor-Arrays
Highly versatile and low cost solution for the design and implementation of multi-touch sensitive surfaces than be designed act as a thin touch sensitive sheet or that be mounted onto any rigid surface to make the surface touch-sensitive.
A series of Electrodes in Columns perpendicular to R rows will generate an Array of C * R sensitive cells.
The distance between the electrode bands will define the Interface size and the spatial resolutions.
Fine resolutions of e.g. 2.54mm enable to build high precision XYZ Maps for e.g. Medical Applications.
Finger Size resolutions enable to produce low cost and versatile touch sensitive parts for controllers, IoT, instruments, and other input control tools or indoor/oudtdoor and immersive games environments.
Hand-Size or Foot-Size or higher resolutions enable to explore larger sensing scale from a few square meters to a whole building floor for a highly competitive cost and granted efficiency.
Our paper-based force sensing technology is being industrialized and and in continuous development since 2020 with MOOS and numerous other partners in Europe and North America sharing this know-how.
Multi-Disciplinary Research Network
Papier Logik technologies started being explored since 2003 in specialized research centers at Pagora INP-Grenoble, France, and APPI Monash Uni. Melbourne, Australia. These research in Materials Sciences quickly found a strong development potential and multi-disciplinary collaborations started with other engineering labs in electronics and computer science under the lead of the MUSICTECH and PPRC research center at McGill University, Canada.
This research resulted in a PhD thesis on paper-based touch sensors for Digital Music Instruments, and various other related Master or PhD Thesis world-wide. We also published various conference publications and journal articles such as this article in the Computer Music Journal, MIT Press in 2014.
Global Knowledge for Local Life-Cycles
Paper-based electronics can be produced, used and recycled or disposed locally with a low carbon print and this can be done everywhere there is a renewable access to fundamental resources such as wood or other organic fibers and water.
Thus, basically any country in the world can make clever use of among the oldest and best industrial processes along with our project database to develop local, autonomous and sustainable electronic industries.
Join an International network of a variety of scholars, designers, researchers, artists, or else just Geeks that already benefit and contribute to this world-wide project. Strengthen local collaborative antennas and provide access to those technologies to ensure an optimized economic and ecologic Life-Cycle for this Project.
It is never too late for getting back to studies and the internet can make science easier and more entertaining: the Grow Seeds pages were written to re-initiate you to basic knowledge for a useful and safe practice of electronics.
Multi-Applicative Technologies
The Papier Logik Project aims to provide a full Data Base of Fundamental Knowledge, Know How, Resources and Tools that are linked to our Research and Developments.
These resources can enable anyone to make use of sustainable goods through a variety of Application examples.
We then hope you will find great usage of these project resources to learn, practice, produce, repair hack and re-invent your own custom electronic devices and future technologies.
A more Efficient and more Sustainable Development Potential
Efficiency is not only how good is a tool but also how Sustainable it is: if a knife cuts well but breaks easily, this is not sustainable, especially if its life-cycle require consequent water and energy consumption and if materials are not recycled.
We aim to find the best compromise between high products efficiency, high usage resilience and low economic and ecologic impact, which involves to explore various fields of sciences and technologies.