Project Details
Abstract
As the complexity of integrated circuits increases, the demanding for sensor applications is more and more urgent. Among them, the magnetic field sensing devices and applications are an important technology. Since few magnetic devices and circuits are now available the development is very urgent for practical applications. Therefore, this project is dedicated to new magnetic memory devices and application circuits.In this project, the key research targets are(1) new device mechanism of changing the differential output current to store data by Lorentz force effect that is built by an internal metal wire or metal loop to generate local magnetic field above the memory cell;(2) new memory cell that consists of a magnetic field sensitive BiNMOS and MAGFET with a wire current or a coil current (metal loop);(3) CMOS process compatible and novel differential structure and multi-value memory designs and applications; and(4) Spice memory device circuit model with Lorentz force effect.Many design techniques will be proposed in this project to achieve the circuit performance of the Lorentz CMOS differential, multi-value memory design, writing, readout and application circuits. As compared to the most advanced prior art, the research target is very innovative and challenging. Development results of this project shall be very innovative. Besides, this project shall be very helpful to both the academic research and technical progress of microelectronics community as well as student training on analog/mixed-signal /memory, sensor and interface applications circuit design.
Project IDs
Project ID:PB10907-2894
External Project ID:MOST109-2221-E182-052
External Project ID:MOST109-2221-E182-052
Status | Finished |
---|---|
Effective start/end date | 01/08/20 → 31/07/21 |
Keywords
- magnetic sensor
- CMOS
- integrated circuit
- lorentz force
- differential multi-value memory
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