In this talk, I will present a new computational design and manufacturing workflow that draws inspiration from computer architectures, programing languages, and program synthesis. I will describe how designs can be synthesized from their functional specifications to the corresponding low-level instructions that are executed on intelligent manufacturing hardware.
Blockchain technology and cryptocurrencies are poised to influence the rate and direction of innovation. By allowing firms to perform costless verification, blockchain lowers the cost of auditing transaction information and allows new marketplaces to emerge. Adding a distributed ledger to the mix allows marketplaces to be bootstrapped without the need for traditional intermediaries. How will this technology challenge existing revenue models? What impact will it have on the regulation, auction, and provision of public goods, software, identity, and reputation systems? With research grounded in economic theory, Catalini will discuss how blockchain is poised to upset the global market.
Part I: Frontiers of Technology - Secure AI Labs: Streamlines data access for business analytics - Lightelligence: Optical chips for machine learning - Zapata Computing: Algorithms for quantum computing - Labber: Firmware for quantum computing - Top Flight Technologies: Heavy lift, long range hybrid-electric UAVs - DeepMagic: Vision & AI for frictionless retail
Part II: Smart Manufacturing - Inkbit: Vision-based 3D printing - Righthand Robotics: Robots for piece-picking and packaging - DUST Identity: Trusted physical identity with diamond dust - Sentenai: Optimizing operational data for equipment monitoring - BlinkAI: Imaging AI for autonomy, robotics, sensing
Lithographic nanofabrication is often limited to successive fabrication of two-dimensional (2D) layers. We present a strategy for the direct assembly of 3D nanomaterials consisting of metals, semiconductors, and biomolecules arranged in virtually any 3D geometry. We used hydrogels as scaffolds for volumetric deposition of materials at defined points in space. We then optically patterned these scaffolds in three dimensions, attached one or more functional materials, and then shrank and dehydrated them in a controlled way to achieve nanoscale feature sizes in a solid substrate. We demonstrate that our process, Implosion Fabrication (ImpFab), can directly write highly conductive, 3D silver nanostructures within an acrylic scaffold via volumetric silver deposition. Using ImpFab, we achieve resolutions in the tens of nanometers and complex, non–self-supporting 3D geometries of interest for optical metamaterials.