Why did you choose to work with a 28-nanometre technology node?
Sharan: Internally, we refer to the 28-nanometre process node as the ‘Goldilocks node’ because it offers sufficient speed, incorporates power-saving features in the node’s design, and is relatively cost-effective. It is the last process node where traditional planar transistors are used before transitioning to FinFET transistors, which are more complex and expensive, particularly in the case of 16-nanometre and lower nodes. Developing for FinFET nodes presents greater challenges and costs, making 28 nanometres an ideal choice that provides the desired performance, power efficiency, and manageability of process technology without breaking the bank. Hence, the fitting nickname ‘Goldilocks.’
Shashwath: Though it was not a primary factor in our decisionmaking, the 28-nanometre process node does not pose export control issues from the US. Access to this node is freely granted. In contrast, for the latest process nodes, a separate licence is required, and the associated paperwork could have caused significant delays, possibly extending to around six months or even longer. So, beyond its technical advantages, the 28-nanometre node also offers streamlined access, aligning perfectly with our needs for the first year of development.
Can you give me an example of where 28-nanometre nodes are used in real life?
Sharan: Xilinx FPGAs, such as Artix 100 and DS 200, are typically fabricated at 28 nanometres. The first-generation Vertex 7 series was produced at 28 nanometres. The very first version of the Apple Watch was manufactured using a 28-nanometre process. Many automotive chips are manufactured using the 28-nanometre process.
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TRULY INNOVATIVE ELECTRONICS -INNOVATION UPDATES
Amongst numerous press releases of new products received by us, these are the ones we found worthy of the title Truly Innovative Electronics
Elastomer enhancing smart wearable performance
A high-tech, flexible wearable device made from the innovative elastomer material
Nanotechnology based noninvasive cancer diagnostics
Nanoflake sensors built from indium oxide with platinum and nickel detect changes in isoprene
Space communication with silent amplifiers
In the new communication system from researchers at Chalmers University of Technology, in Sweden, a weak optical signal (red) from the spacecraft's transmitter can be amplified noisefree when it encounters two so-called pump waves (blue and green) of different frequencies in a receiver on Earth.
Advancements in TOPCon solar cells
The structure and performance of tandem devices with highly passivated TOPCon bottom cells
Quantum leap in magnetism refines superconductors
Rice University physicists have uncovered key magnetic and electronic properties in kagome magnets, structures resembling basket-weaving patterns.
Sensor targets food antioxidants
A research team from Hunan City University and Xiangtan University in China has developed a sensor for detecting TBHQ, a food antioxidant used in oils and fats, addressing health concerns at high concentrations.
Data sensing with repurposed RFID tags
UC San Diego researchers have advanced passive data collection with a breakthrough in battery-free sensing.
Seal-inspired sensors to safeguard offshore wind farms
Schematic structure of the seal whisker-inspired flow sensors
Artificial nose identifies scents accurately
Artificial nose identifies scents accurately
