Badawi, Diaa Hisham Jamil2018-01-102018-01-102018-012018-012018-02-10http://hdl.handle.net/11693/35726Cataloged from PDF version of article.Thesis (M.S.): Bilkent University, Department of Electrical and Electronics Engineering, İhsan Doğramacı Bilkent University, 2018.Includes bibliographical references (leaves 67-75).Dot product-based operations in neural net feedforwarding passes are replaced with an ℓ₁-norm inducing operator, which itself is multiplication-free. The neural net, which is called AddNet, retains attributes of ℓ₁-norm based feature extraction schemes such as resilience against outliers. Furthermore, feedforwarding passes can be realized using fewer multiplication operations, which implies energy efficiency. The ℓ₁-norm inducing operator is differentiable w.r.t its operands almost everywhere. Therefore, it is possible to use it in neural nets that are to be trained through standard backpropagation algorithm. AddNet requires scaling (multiplicative) bias so that cost gradients do not explode during training. We present different choices for multiplicative bias: trainable, directly dependent upon the associated weights, or fixed. We also present a sparse variant of that operator, where partial or full binarization of weights is achievable. We ran our experiments over MNIST and CIFAR-10 datasets. AddNet could achieve results that are 0:1% less accurate than a ordinary CNN. Furthermore, trainable multiplicative bias helps the network to converge fast. In comparison with other binary-weights neural nets, AddNet achieves better results even with full or almost full weight magnitude pruning while keeping the sign information after training. As for experimenting on CIFAR-10, AddNet achieves accuracy 5% less than a ordinary CNN. Nevertheless, AddNet is more rigorous against impulsive noise data corruption and it outperforms the corresponding ordinary CNN in the presence of impulsive noise, even at small levels of noise.xiv, 78 leaves : charts (some color) ; 30 cmEnglishinfo:eu-repo/semantics/openAccessDeep LearningConvolutional Neural Networkℓ₁ NormEnergy EfficiencyBinary WeightsImpulsive NoiseThesisB157365