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ORCIDHuber Nieto-Chaupis
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2020 – today
- 2023
[c90]Huber Nieto-Chaupis:
Machine Learning As a Blind Creator of Infinite Algebras in the Context of Strings Theory. AIBThings 2023: 1-5- [c89]Huber Nieto-Chaupis:
Principles of a Prospective Internet of Public Viral Surveillance. AIBThings 2023: 1-5 - [c88]Huber Nieto-Chaupis:
Coherent Molecular Communications By Using Quantum Mechanics. BCD 2023: 308-311 - [c87]Huber Nieto-Chaupis:
Direct Usage of Mitchell Criteria to Identify and Predict the Arrival of Next Global Pandemic. BCD 2023: 312-315 - [c86]Huber Nieto-Chaupis:
Fast Seismic Detection Through Internet of Things Based in Pulse Laser and High Resolution Detector. BCD 2023: 316-319 - [c85]Huber Nieto-Chaupis:
Inherent RC Circuits in Cylindrical Geometries From the Fokker-Planck Equation. BCD 2023: 320-324 - [c84]Huber Nieto-Chaupis:
The Internet of Nanomedicine Things. BCD 2023: 325-328 - [c83]Huber Nieto-Chaupis:
Physics Fundamentals of an Internet of Nanomedicine Things. IEEE Big Data 2023: 3952-3955 - [c82]Huber Nieto-Chaupis:
Kirchhoff's Voltage Law at Neural Synapse From Electric Currents Based at Neurotransmiters. IEEE Big Data 2023: 3956-3960 - [c81]Huber Nieto-Chaupis:
Fundamentals of an Internet of Anti-Viral Things Based at Electromagnetism of a Dual-Role Antenna. ICCE-Berlin 2023: 1-6 - [c80]Huber Nieto-Chaupis:
The Internet of Tall Buildings Surveillance as an Portable System of Hardware-Software Interface. ICCE-Berlin 2023: 1-5 - [c79]Huber Nieto-Chaupis:
The Internet of Brain Things: Theoretical Basis for the Usage of Neuralink Chip. ICCE-Berlin 2023: 1-6 - 2022
- [c78]Huber Nieto-Chaupis:
Proposal of Wireless Measurement of Albumin Excretion Rate at the THz Band. BIBE 2022: 5-10 - [c77]Huber Nieto-Chaupis:
Theoretical Proposal of an Internet of Pandemic Things Network Based at the Sensing of Proteins and Emission of Radiation in Outdoor Spaces. BIBE 2022: 146-151 - [c76]Huber Nieto-Chaupis:
Exploring Geographical Topologies and Diffusion of Monkeypox Infections at the Beginning Pandemic. BIBE 2022: 152-157 - [c75]Huber Nieto-Chaupis:
Neurogenesis as a Probability Amplitude Governed by Charges-Dependent Hamiltonian. BIBE 2022: 339-344 - [c74]Huber Nieto-Chaupis:
Modeling the Electrodynamics of Cellular Uptake of Nanoparticles at Drug Delivery Strategies. BIBE 2022: 345-350 - [c73]Huber Nieto-Chaupis:
Quadratic Spreading of Monkeypox Infections Dictated by the Diffusion Equation: The Case of Central Europe. BIBM 2022: 2860-2864 - [c72]Huber Nieto-Chaupis:
Success and Fail at the Internalization and Expelling of Nanoparticles off Tumor Cells Through Electrodynamics and Diffusion Equation. BIBM 2022: 3556-3561 - [c71]Huber Nieto-Chaupis:
Model of Early Intervention Using Machine Learning: Predicting Monkeypox Pandemic. BIBM 2022: 3680-3685 - [c70]Huber Nieto-Chaupis:
Neurogenesis Based in Quantum Mechanics Governed by Ions Interaction and Coherent States. BIBM 2022: 3686-3691 - [c69]Huber Nieto-Chaupis
, Anthony Alfaro-Acuña:
Teaching of Physics Courses in Epochs of Pandemic: Tablet versus Blackboard. ICETC 2022: 274-278 - [c68]Huber Nieto-Chaupis, Anthony Alfaro-Acuña:
Introducing New Sources of Green Energy from Basic Physics at the Systems Engineering Program of a Private University at Lima Perú. ICETC 2022: 538-543 - [c67]Huber Nieto-Chaupis, Anthony Alfaro-Acuña:
The Management of a Private Peruvian University at Pandemic Times: Assessment of Decisions and Implications on the Key Indicators. ICETC 2022: 555-560 - [c66]Huber Nieto-Chaupis:
Is Omicron Belonging to the Corona Virus Family? A Physics-based Note. INISTA 2022: 1-4 - [c65]Huber Nieto-Chaupis:
Quantum Displacements Dictated by Machine Learning Principles: Towards Optimization of Quantum Paths. IntelliSys (1) 2022: 82-96 - [c64]Huber Nieto-Chaupis:
Entropy of Shannon from Geometrical Modeling of Covid-19 Infections Data: The Cases of USA and India. IntelliSys (1) 2022: 505-513 - [c63]Huber Nieto-Chaupis:
Corona Virus and Entropy of Shannon at the Cardiac Cycle: A Mathematical Model. SAI (3) 2022: 169-178 - [c62]Huber Nieto-Chaupis:
Machine Learning of a Pair of Charged Electrically Particles Inside a Closed Volume: Electrical Oscillations as Memory and Learning of System. SAI (2) 2022: 247-256 - [c61]Huber Nieto-Chaupis:
Simulating the Arnaoutova-Kleinman Model of Tubular Formation at Angiogenesis Events Through Classical Electrodynamics. SAI (1) 2022: 248-254 - [c60]Huber Nieto-Chaupis:
The Machine Learning Principles Based at the Quantum Mechanics Postulates. SAI (1) 2022: 394-403 - [c59]Huber Nieto-Chaupis:
Small Probability of Fatality from Theorem of Bayes at the Monkeypox Pandemic. SNPD 2022: 40-44 - [c58]Huber Nieto-Chaupis:
Quantum Mechanics of Theorem of Bayes Modeled by Machine Learning Principles. SNPD 2022: 45-49 - [c57]Huber Nieto-Chaupis:
The Approach of Machine Learning to Optimize the Bank-Customer Interaction at Pandemic Epochs. SNPD 2022: 50-54 - [c56]Huber Nieto-Chaupis:
Machine Learning and Bayes Probability For Detecting Camouflaged Mini Pandemic at the Waves of Covid-19. SNPD 2022: 120-125 - [c55]Huber Nieto-Chaupis:
Probabilistic Neural Synapse Based in Quantum Mechanics. SNPD 2022: 144-148 - [c54]Huber Nieto-Chaupis:
Theory and Simulation of Multipurpose Antenna for Detection and Degrading of Viruses in Times of Pandemic. SNPD 2022: 179-182 - 2021
- [c53]Huber Nieto-Chaupis:
The Quantum Mechanics Propagator as the Machine Learning Performance in Space-Time Displacements. AIKE 2021: 135-136 - [c52]Huber Nieto-Chaupis:
Bioelectrical Circuit from Charged Proteins as Biomarker of Renal Damage. BIBE 2021: 1-4 - [c51]Huber Nieto-Chaupis:
Modeling Sprouting Angiogenesis by Drift Forces with the Usage of Fokker-Planck Equation. BIBE 2021: 1-5 - [c50]Huber Nieto-Chaupis:
Theory and Parameterization of Infections and Waves by Covid-19: A 6-Countries Data Analysis. BIBE 2021: 1-5 - [c49]Huber Nieto-Chaupis:
Accelerated Virus Spread Driven by Randomness in Human Behavior. BICT 2021: 244-255 - [c48]Huber Nieto-Chaupis:
The Conjunction of Deterministic and Probabilistic Events in Realistic Scenarios of Outdoor Infections. BICT 2021: 256-268 - [c47]Huber Nieto-Chaupis:
Diffusive Nanoparticles and Generation of Repulsive Effects by Artificial Electrical Currents. ICCCS 2021: 1-4 - [c46]Huber Nieto-Chaupis:
Probabilities of Risk Due to Random Aerosol Displacement and Aleatory Social Distancing. ICCCS 2021: 1-4 - [c45]Huber Nieto-Chaupis:
Understanding the Global Data of Infections Cases by Covid-19 Through Gaussian and Trapezoid Models. ICCCS 2021: 1-4 - [c44]Huber Nieto-Chaupis:
Software Engineering For Estimation of Social Distancing in Pandemic Times. SNPD 2021: 21-24 - [c43]Huber Nieto-Chaupis:
Computational Simulation of Charged Nanoparticles Diffusion in Vascular Tissue. SNPD 2021: 82-85 - [c42]Huber Nieto-Chaupis:
Geometrical Schemes as Probabilistic and Entropic Tools to Estimate Duration and Peaks of Pandemic Waves. SNPD 2021: 86-89 - [c41]Huber Nieto-Chaupis:
Nephrine-Albumin Interaction and the Spontaneous Apparition of Series Capacitors in the Renal Glomerulus as Indicator of Kidney Disease. SNPD 2021: 90-93 - [c40]Huber Nieto-Chaupis:
Spreading of Corona Virus in Central Europe: The Cases of Italy and Spain and the Very Beginning of Pandemic. SNPD 2021: 94-97 - [c39]Huber Nieto-Chaupis:
The Internet of Tall Buildings. SSCI 2021: 1-4 - [c38]Huber Nieto-Chaupis:
Theoretical Artificial Intelligence Based on Shannon Entropy to Identify Strains in Covid-19 Pandemic. TransAI 2021: 45-46 - [c37]Huber Nieto-Chaupis:
Proteins-Based Circuits in an Intelligent Internet of Bio-Nano Things Network for Molecular Diagnostic of Renal Damage. TransAI 2021: 68-71 - [c36]Huber Nieto-Chaupis:
Predictive Theory of Covid-19 Infections at European Countries Through Bessel Functions: Past and Present. TransAI 2021: 72-73 - 2020
- [c35]Huber Nieto-Chaupis:
Convolution-based Machine Learning To Attenuate Covid-19's Infections in Large Cities. AIKE 2020: 148-152 - [c34]Huber Nieto-Chaupis:
Computational Simulation of Artificial Nanoparticles Paths. AIKE 2020: 193-197 - [c33]Huber Nieto-Chaupis:
Ions Diffusion and Electrodynamics Interactions Inside Pancreatic Beta Cells. BIBE 2020: 147-152 - [c32]Huber Nieto-Chaupis:
Probabilistic Theory of Efficient Internalization of Nanoparticles at Targeted Drug Delivery Strategies. BIBE 2020: 180-184 - [c31]Huber Nieto-Chaupis:
Classical Electrodynamics and Green Functions with the Keller-Segel Equation. BIBE 2020: 185-189 - [c30]Huber Nieto-Chaupis:
Theory of Virus Public Infection Through The Weiss Approach. BIBE 2020: 349-353 - [c29]Huber Nieto-Chaupis:
PROSISY: PRospective Stroke Identification SYstem Based on Cognitive Radio Theory and Machine Learning. CBMS 2020: 99-103 - [c28]Huber Nieto-Chaupis:
The Feynman Propagator to Model Molecular Communications Between an Engineered Nanodevice and Beta Cells. CBMS 2020: 203-207 - [c27]Huber Nieto-Chaupis:
Nano Currents and the Beginning of Renal Damage: A Theoretical Model. CBMS 2020: 344-349 - [c26]Huber Nieto-Chaupis:
Nanodevices Based on Quantum Mechanics and Classsical Electrodynamics as Vascular Endothelial Growth Blockers to Detain Angiogenesis. CBMS 2020: 481-485
2010 – 2019
- 2019
- [c25]Huber Nieto-Chaupis:
Cheating the Beta Cells to Delay the Beginning of Type-2 Diabetes Through Artificial Segregation of Insulin. BICT 2019: 1-13 - [c24]Huber Nieto-Chaupis:
Physics-Based Nanomedicine to Alleviate Anomalous Events in the Human Kidney. BICT 2019: 14-27 - [c23]Huber Nieto-Chaupis:
Frequency-Based Releasing of Insulin in the Langerhans Islets To Counteract the Beginning of the Type-2 Diabetes in Pre-diabetes Patients. CCWC 2019: 569-573 - [c22]Huber Nieto-Chaupis:
Face To Face with Next Flu Pandemic with a Wiener-Series-Based Machine Learning: Fast Decisions to Tackle Rapid Spread. CCWC 2019: 654-658 - [c21]Huber Nieto-Chaupis:
Macrophage-Like Nanorobots To Anticipate Bacterial Dynamics. CCWC 2019: 873-879 - [c20]Huber Nieto-Chaupis:
The Feynman Path Integral and Machine Learning Algorithms to Characterize and Anticipate Bacteria Chemotaxis in a Host Healthy Body. CCWC 2019: 969-973 - [c19]Huber Nieto-Chaupis:
The Feynman-Kac Formula to Estimate the Very Beginning of the Diabetic Nephropathy. CISS 2019: 1-4 - [c18]Huber Nieto-Chaupis:
Bacteria Nano Communications Described by a Machine Learning Theory Based on the Feynman Path Integral. CISS 2019: 1-4 - [c17]Huber Nieto-Chaupis:
Formalisms of Quantization in High Intensity Fields: Quantum Mechanics Meets Classical Electrodynamics. CISS 2019: 1-4 - 2018
- [c16]Huber Nieto-Chaupis:
Optimization of Handover Events for an Efficient Resource Allocation in an Internet of Things Network Through Computational Simulation Based on The Moivre-Laplace Theorem. ISC2 2018: 1-6 - [c15]Huber Nieto-Chaupis:
Identification of the Social Duality: Street Criminality and High Vehicle Traffic in Lima City by Using Artificial Intelligence Through the Fisher-Snedecor Statistics and Shannon's Entropy. ISC2 2018: 1-6 - [c14]Huber Nieto-Chaupis:
Shannon - Entropy - Based Artificial Intelligence Applied to Identify Social Anomalies in Large Latin American Cities. Sarnoff Symposium 2018: 1-4 - 2017
- [c13]Huber Nieto-Chaupis:
Prospects for anticipating kidney damage in type-2 diabetes patients through the sensing of albumin passing through the renal glomerulus. BHI 2017: 257-260 - [c12]Huber Nieto-Chaupis:
Prospective implementation of topics related to the Internet of bio-nano things in the capstone project in the electrical engineering program. ICACIT 2017: 1-4 - [c11]Huber Nieto-Chaupis:
Modeling the measurement of the quality of education through the full evaluation of capstone project in the program of electrical engineering. ICACIT 2017: 1-4 - [c10]Huber Nieto-Chaupis:
RASUS: Rapid Assistance System through Uber-inspired Software for localization on-line of nurses and doctors. MeMeA 2017: 204-209 - [c9]Huber Nieto-Chaupis:
Modeling the electric degradation of podocytes and detection of albumin for the early diagnostics of the glomerulus's damage. MeMeA 2017: 385-390 - 2016
- [c8]Huber Nieto-Chaupis:
How Effective are Teleconsults to Persuade Patients of Pulmonary Tuberculosis of Avoiding to Use Public Transport at Lima City? CBMS 2016: 333-334 - [c7]Huber Nieto-Chaupis:
Monte Carlo simulation for prediction of worsening conditions of type-2 diabetes patients at peri-urban zones of lima city. CLEI 2016: 1-6 - [c6]Huber Nieto-Chaupis:
A study of a possible scenario of Zika virus outbreak and rapid intervention using a mathematical and computational simulation. LA-CCI 2016: 1-2 - [c5]Huber Nieto-Chaupis:
Computational simulation for identification, evaluation and relocation of pregnant women in a possible zika infection outbreak in South American cities. SCCC 2016: 1-5 - 2015
- [c4]Huber Nieto-Chaupis, Mitsuko Caballero, H. Matta-Solis, R. Perez-Siguas, Sheila Blas, E. Carranza-Manrique, Edith Contreras, Gloria Quispe, Sandy Ramirez, J. Rocha:
Preventing Risk Situations at Type-II Diabetes Mellitus Patients Through Continuous Glucose Monitoring and Prediction-Based Teleconsults. CBMS 2015: 27-28 - [c3]Huber Nieto-Chaupis:
Predictive Control of the mineral particle size with kernel-reduced volterra models in a balls mill grinding circuit. ISIE 2015: 113-118 - 2014
- [c2]Huber Nieto-Chaupis:
On the usage of Dirac Delta functions with nonlinear argument in high order I/O integrals. I2MTC 2014: 519-524 - [c1]Huber Nieto-Chaupis:
QoS evaluation for end user mobility for accessing classical and QKD networks. LATINCOM 2014: 1-4
Coauthor Index
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