Diverse models have been proposed over the past years to explain the exhibiting behavior
of memristors, the fourth fundamental circuit element. The models varied in complexity …

Since the 2008-dated discovery of memristor behavior at the nano-scale, Hewlett Packard is
credited for, a large deal of efforts have been spent in the research community to derive a …

The memristor represents the key circuit element for the development of the constitutive
blocks of future non-volatile memory architectures and neuromorphic systems. However …

The inevitable variability within electronic devices causes strict constraints on operation,
reliability and scalability of the circuit design. However, when a compromise arises among …

This book presents a collection of chapters offering practical solutions and design, modeling,
and implementation insights to address current research problems in memristors, memristive …

The nonvolatile memory property of a memristor enables the realization of new methods for
a variety of computational engines ranging from innovative memristive-based neuromorphic …

Memristor, the fourth basic circuit element, has shown great potential in neuromorphic circuit
design for its unique synapse-like feature. However, though the continuous resistance state …

Memristor prevails in thin-film technology and became a favorable candidate over emerging
semiconductor devices because of its non-volatility, low power consumption, nanoscale …

It is only very recently that the memristor, the fourth missing passive element, was
discovered, as technological advances and the scalingdown to nanometre dimensions in …

Since 2007, when Stanley Williams and his team at HP Labs constructed a nanoelectronic
device [1] showing certain fingerprints of a memristor, there has been a resurgence of …