Vector Matrix Multiplication (VMM) is a fundamental operation in machine learning algorithms focused on artificial neural networks and also many simulation codes. Implementations based on crossbar arrays provide a promising approach to perform this operation with an analogue circuit. In comparison to purely digital solutions, significant improvements in processing speed and power consumption can be expected when applying this approach. However, securing the accuracy is more difficult than in the digital case. Primary reasons include nonlinearities of essential resistive elements and non-zero resistances of wiring lines. Many publications have dealt with this topic in the recent years analysing the different influences in different ways. We ...
Conventional digital computers can execute advanced operations by a sequence of elementary Boolean f...
Memristor crossbar array is promising for realizing artificial neural networks. Wire resistance in c...
In this Chapter, we review the recent progress on resistance drift mitigation techniques for resisti...
Abstract—The matrix-vector multiplication is the key operation for many computationally intensive al...
Recent advances in nanoscale resistive memory devices offer promising opportunities for in-memory co...
Modern neuromorphic deep learning techniques, as well as unsupervised techniques like the locally co...
Computation-in-memory using memristive devices is a promising approach to overcome the performance l...
Problems involving discrete Markov Chains are solved mathematically using matrix methods. Recently, ...
Digital electronics has given rise to reliable, affordable, and scalable computing devices. However,...
The crossbar nonidealaties may considerably degrade the accuracy of matrix multiplication operation,...
Recently, an in-memory analog circuit based on crosspoint memristor arrays was reported, which enabl...
Boolean matrix multiplication (BMM) is a fundamental problem with applications in graph theory, grou...
The recent emerging memristor can provide non-volatile memory storage but also intrinsic computing f...
This work addresses the reliability of RRAM, with a focus on conductance variation and its impact on...
Conventional digital computers can execute advanced operations by a sequence of elementary Boolean f...
Memristor crossbar array is promising for realizing artificial neural networks. Wire resistance in c...
In this Chapter, we review the recent progress on resistance drift mitigation techniques for resisti...
Abstract—The matrix-vector multiplication is the key operation for many computationally intensive al...
Recent advances in nanoscale resistive memory devices offer promising opportunities for in-memory co...
Modern neuromorphic deep learning techniques, as well as unsupervised techniques like the locally co...
Computation-in-memory using memristive devices is a promising approach to overcome the performance l...
Problems involving discrete Markov Chains are solved mathematically using matrix methods. Recently, ...
Digital electronics has given rise to reliable, affordable, and scalable computing devices. However,...
The crossbar nonidealaties may considerably degrade the accuracy of matrix multiplication operation,...
Recently, an in-memory analog circuit based on crosspoint memristor arrays was reported, which enabl...
Boolean matrix multiplication (BMM) is a fundamental problem with applications in graph theory, grou...
The recent emerging memristor can provide non-volatile memory storage but also intrinsic computing f...
This work addresses the reliability of RRAM, with a focus on conductance variation and its impact on...
Conventional digital computers can execute advanced operations by a sequence of elementary Boolean f...
Memristor crossbar array is promising for realizing artificial neural networks. Wire resistance in c...
In this Chapter, we review the recent progress on resistance drift mitigation techniques for resisti...