The silicon-on-thin-buried-oxide (SOTB) process technology allows reduction of both active and standby current. The first device built on the process is a 32bit Arm Cortex embedded controller that operates up to 32MHz (64MHz in boost mode) with 20 μA/MHz active current and only 150 nA deep standby current.
Shown at the Electronica trade show in Munich this week for the first time, the controller has approximately one-tenth that of conventional low-power MCUs says Renesas, and opens up the opportunity for sourcing energy from light or heat.
This then allows maintenance-free connected IoT sensing devices with endpoint intelligence for applications in industrial, business, residential, agricultural, healthcare, and public infrastructure, as well as health and fitness apparel, shoes, wearables, smart watches, and drones. Renesas has already begun supplying the new embedded controller to beta customers.
In the SOTB process, an oxide film (the BOX layer) is buried under a thin silicon layer on the wafer substrate. No impurities are doped to the thin silicon layer which makes it possible to maintain stable operation at low voltages so that the resulting devices can therefore deliver high computing performance with power efficiency. At the same time, the potential of the silicon substrate below the BOX layer is controlled with a back bias circuit to reduce leakage currents to further suppress standby power consumption.
The R7F0E also includes a configurable Energy Harvest Controller (EHC) function that connects directly to ambient energy sources such as solar, vibration, or piezoelectric, while protecting against harmful inrush current at start-up. The EHC also manages the charging of external power storage devices such as supercapacitors or optional rechargeable batteries.
The R7F0E can sense and capture external analog signals at all times via its internal 14bit Analogue-to-Digital Converter (ADC) as it consumes only 3 uA current. It can retain up to 256 KB of SRAM data content while consuming just one nA per each KB of SRAM, and can also provides graphics data conversion including rotation, scroll, and colorization by incorporating low-power hardware techniques for driving an external display using Memory-In-Pixel1 LCD technology that consumes virtually no power to retain an image.
“I am very pleased that Renesas achieved this milestone to productize our SOTB technology into a first-of-its-kind solution in the energy harvesting market,” said Yoshikazu Yokota, Executive Vice President and General Manager of Industrial Solution Business Unit of Renesas. “By removing the need for batteries, or the need to replace batteries, new markets will open for us and our customers.”
“Energy harvesting will become a mandatory technology for a smart society and Renesas is poised to lead and expand this technology, and this market. Renesas continues to push forward with e-AI to realize AI at the endpoint, in embedded devices. Looking forward, our SOTB technology will expand our reach into use cases where combining e-AI and energy harvesting will make a very large positive impact to our day-to-day lives.”
For security, which is a key consideration for IoT nodes an dmore difficult to implement in an eenrgy harvesting system, the device includes a true random number generator, a unique ID for each R7F0E device and AES encryption acceleration.
Samples of the R7F0E are available now for beta customers, and samples are scheduled to be available for general customers from July 2019. Mass production is scheduled to start from October 2019.