The interest for developing smart systems based on interconnected objects is growing fast. It is assumed that 50 billion objects will be connected in 2020. The main components of “Internet of Things” (IoT) devices are autonomous battery-operated smart embedded systems comprising RF circuits for communications, digital circuits for data processing, memory for data storage and analog circuits such as sensors, filters, converters, cameras, GPS systems... Consequently, the key requirements for IoT devices are ultra-low power, high processing capabilities, wireless communication and autonomy. In battery-operated Machine to Machine (M2M) and Machine to Human (M2H) operations, the processing cycle includes sleep, wake-up, sense, store, process and send actions. With smart connected objects or mobile devices used as terminals, the need to store and access an increasing amount of data requires energy-efficient embedded architectures. However, the continuously decreasing size of devices and increasing operation frequency lead to critical power consumption and heating issues.
As pointed out by the ITRS, one of the best solutions to stop this trend is the modification of the memory hierarchy by the integration of non-volatile memories like Spin Transfer Torque Magnetic Random Access Memory (STT-MRAM), which would immediately minimize static power and pave the way towards normally-off/instant-on computing. Moreover, the Magnetic Tunnel Junctions (MTJs), basic elements of MRAMs, can also be used as RF emitter/receiver and magnetic field sensor. However, so far, MTJs are optimized to perform each function independently. Using the same device for all the functions would allow integrating them in the same chip. To tackle the key issues of monolithic heterogeneous integration, the goal of the GREAT project is to co-integrate multiple functions like sensors, RF receivers and logic/memory together within CMOS by adapting the STT-MTJs to a single baseline technology enabling logic, memory, and analog functions in the same System-on-Chip (SoC), as the enabling technology platform for M2M and M2H IoT. This will lead to a unique cell technology called Multifunctional Standardized Stack (MSS). Thus, GREAT will achieve the same goal as heterogeneous integration but in a much simpler way since the it will enable different functions using the same technology.