TY - JOUR
T1 - Low power memristive gas sensor architectures with improved sensing accuracy
AU - Khandelwal, Saurabh
AU - Ottavi, Marco
AU - Martinelli, Eugenio
AU - Jabir, Abusaleh
N1 - Funding Information:
The work is funded by the Leverhulme Trust Research Project Grant, under Grant No. RPG-2017-344.
Publisher Copyright:
© 2022, The Author(s).
PY - 2022/8
Y1 - 2022/8
N2 - Memristive devices, traditionally considered for memory, logic, and neuromorphic systems, are exhibiting many interesting properties for applications in a variety of areas, such as in sensing chemicals. However, any realistic approach based on these devices must take into account their susceptibility to process and parametric variations. When used for sensing purposes this, together with wire resistance, can significantly degrade their sensing accuracy. To this end, we propose novel memristive gas sensor architectures that can significantly reduce these effects in a predictable manner, while improving accuracy and overall power consumption. Additionally, we show that in the absence of gasses this architecture can also be configured to realize multifunction logic operations as well as Complementary Resistive Switch with low hardware overhead, thereby enhancing resource reusability. We also present a method for further improving power consumption and measurability by manipulating a device’s internal barrier. Our results show that the proposed architecture is significantly immune to process and parametric variations compared to a single sensor and almost unaffected by wire resistance, while offering much higher accuracy and much lower power consumption compared to existing techniques.
AB - Memristive devices, traditionally considered for memory, logic, and neuromorphic systems, are exhibiting many interesting properties for applications in a variety of areas, such as in sensing chemicals. However, any realistic approach based on these devices must take into account their susceptibility to process and parametric variations. When used for sensing purposes this, together with wire resistance, can significantly degrade their sensing accuracy. To this end, we propose novel memristive gas sensor architectures that can significantly reduce these effects in a predictable manner, while improving accuracy and overall power consumption. Additionally, we show that in the absence of gasses this architecture can also be configured to realize multifunction logic operations as well as Complementary Resistive Switch with low hardware overhead, thereby enhancing resource reusability. We also present a method for further improving power consumption and measurability by manipulating a device’s internal barrier. Our results show that the proposed architecture is significantly immune to process and parametric variations compared to a single sensor and almost unaffected by wire resistance, while offering much higher accuracy and much lower power consumption compared to existing techniques.
KW - CRS
KW - Logic
KW - Memristive magnification
KW - Memristor
KW - Process variation
KW - Sensor
KW - Wire resistance
UR - http://www.scopus.com/inward/record.url?scp=85130260541&partnerID=8YFLogxK
U2 - 10.1007/s10825-022-01890-0
DO - 10.1007/s10825-022-01890-0
M3 - Article
AN - SCOPUS:85130260541
SN - 1569-8025
VL - 21
SP - 1005
EP - 1016
JO - Journal of Computational Electronics
JF - Journal of Computational Electronics
IS - 4
ER -