Computation-In-Memory (CIM) using memristor devices provides an energy-efficient hardware implementation of arithmetic and logic operations for numerous applications, such as neuromorphic computing and database query. However, memristor-based CIM suffers from various non-idealities such as conductance drift, read disturb, wire parasitics, endurance and device degradation. These negatively impact the computation accuracy of CIM. It is therefore essential to deal with these non-idealities and fabrication imperfections in order to harness the full potential of CIM. This paper discusses the non-ideality challenges and provides potential solutions. Furthermore, the paper outlines the potential future directions for CIM architectures.Green Open A...
© 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
Computation-in-memory (CIM) is one of the most appealing computing paradigms, especially for impleme...
Memristive device or memristor is a promising emerging technology due to its good scalability, near-...
Emerging computing applications (such as big-data and Internet-of-things) are extremely demanding in...
Conventional computing architectures and the CMOS technology that they are based on are facing major...
In-memory computing is a promising computing paradigm due to its capability to alleviate the memory ...
This paper briefly discusses a new architecture, Computation-In-Memory (CIM Architecture), which per...
In recent years, we are witnessing a trend moving away from conventional computer architectures towa...
Memristive devices are promising candidates as a complement to CMOS devices. These devices come with...
Today's computing architectures and device technologies are incapable of meeting the increasingly st...
Today's computing architectures and device technologies are unable to meet the increasingly stringen...
\u3cp\u3eCMOS technology and its sustainable scaling have been the enablers for the design and manuf...
The computation goals of the digital computing world have been segmented into different factions. Th...
Memristors have gained increasing interest recently as emerging memory technologies. Their unique ab...
© 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
Computation-in-memory (CIM) is one of the most appealing computing paradigms, especially for impleme...
Memristive device or memristor is a promising emerging technology due to its good scalability, near-...
Emerging computing applications (such as big-data and Internet-of-things) are extremely demanding in...
Conventional computing architectures and the CMOS technology that they are based on are facing major...
In-memory computing is a promising computing paradigm due to its capability to alleviate the memory ...
This paper briefly discusses a new architecture, Computation-In-Memory (CIM Architecture), which per...
In recent years, we are witnessing a trend moving away from conventional computer architectures towa...
Memristive devices are promising candidates as a complement to CMOS devices. These devices come with...
Today's computing architectures and device technologies are incapable of meeting the increasingly st...
Today's computing architectures and device technologies are unable to meet the increasingly stringen...
\u3cp\u3eCMOS technology and its sustainable scaling have been the enablers for the design and manuf...
The computation goals of the digital computing world have been segmented into different factions. Th...
Memristors have gained increasing interest recently as emerging memory technologies. Their unique ab...
© 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
Computation-in-memory (CIM) is one of the most appealing computing paradigms, especially for impleme...
Memristive device or memristor is a promising emerging technology due to its good scalability, near-...