This book examines quantum neural networks through renormalization techniques, supersymmetric field theory, and noisy harmonic oscillator systems. The book's analysis covers adaptive beamforming applications, brain modeling, gravitational control mechanisms, and mixed-state dynamics in superstring theory, and also includes:
- Comprehensive analysis of quantum neural networks through renormalization techniques and supersymmetric field theory applications in computational modeling
- Investigation of quantum field dynamics with noise integration, filtering mechanisms, and scattering processes in curved spacetime environments
- Study of adaptive beamforming methodologies combined with quantum neural networks for brain modeling and evolving field system applications
- Examination of mixed-state dynamics in superstring theory frameworks with emphasis on quantum noisy fields and supersymmetric effects
- Analysis of extended Kalman filter integration with quantum neural networks for transmission line control and field estimation optimization
The work explores extended Kalman filter methodologies for transmission line control, field estimation, and symmetry-broken dynamics in signal processing systems for advanced computational modeling applications.
This title has been co-published with Manakin Press. T&F does not sell or distribute the print editions in Bangladesh, Bhutan, India, Nepal, Pakistan, and Sri lanka.
Table of Contents:
1. QNN Using Renormalization of Fields and Supersymmetric Field Theory 2. Quantum Neural Networks: Scattering, Superconductivity, MRI, and EEG Modeling 3. QNNs with Noisy Harmonic Oscillators, Strings, and Gravitational Control 4. Adaptive Beamforming and QNNs for Evolving Brain and Field Models 5. Quantum Noisy Fields and Supersymmetric Effects: QNNs with Mixed-State Dynamics in Superstring Theory 6. Quantum Fields, Signal Theory, and QNNs via Symmetry-Broken Dynamics 7. Quantum Field Theory with Noise, Filters, Scattering, and Curved Spacetime 8. Quantum Field Theory with Noise, Filters, Scattering, and Curved Spacetime 9. QNNs and EKF for Transmission Line Control and Field Estimation
About the Author :
Harish Parthasarathy is Professor in the Department of Electronics & Communication Engineering at Netaji Subhas University of Technology (NSUT), New Delhi, India. Based at the university's Delhi campus, he specializes in advanced theoretical and applied research within the fields of electronics and communication systems. Professor Parthasarathy's work encompasses various aspects of electronics and communication engineering, contributing to both undergraduate and graduate-level instruction while maintaining active research engagement in his specialized areas of study.
