In detection systems, the noise-equivalent target (NET) is the intensity of a target measured by a system when the signal-to-noise ratio of the system is 1. Noise-equivalent temperature is an example for noise-equivalent target. * v * t * e (Wikipedia).
Sound vs. Noise: What’s the Actual Difference? (Part 1 of 3)
Noise and sound are not the same thing… really, they aren’t! What exactly is noise? Part 2 of 3 - https://youtu.be/XhFhK97hrdY Part 3 of 3 - https://youtu.be/yTyYZFcxGGQ Read More: Signal-to-Noise Ratio and Why It Matters https://www.lifewire.com/signal-to-noise-ratio-3134701 “You
From playlist Seeker Plus
Physics - Mechanics: Sound and Sound Waves (13 of 47) Sound Intensity at a Distance
Visit http://ilectureonline.com for more math and science lectures! In this video I will show you how to calculate I=? at distances of 10m, 1000m, and 10,000m.
From playlist PHYSICS MECHANICS 5: WAVES, SOUND
Physics - Mechanics: Sound and Sound Waves (7 of 47) Sound Intensity
Visit http://ilectureonline.com for more math and science lectures! In this video I will explain the basics of the intensity of sound (speaking, whisper, and screaming!).
From playlist MOST POPULAR VIDEOS
In this video i demonstrate sound waves interference and standing waves from loudspeaker used sound sensor. The frequency on loudspeaker is about 5500Hz. Enjoy!!!
From playlist WAVES
Physics - Mechanics: Sound and Sound Waves (8 of 47) Sound Intensity: Decibels
Visit http://ilectureonline.com for more math and science lectures! In this video I will explain what is a decibel and give examples of decibels.
From playlist PHYSICS MECHANICS 5: WAVES, SOUND
Sound Intensity Level in Decibels & Distance - Physics Problems
This physics video tutorial provides a basic introduction into sound intensity level in decibels. it explains how to calculate the sound level in decibels given the sound intensity and how to calculate the sound intensity given the intensity level in decibels. It also explains how to cal
From playlist New Physics Video Playlist
Lecture 9/16 : Ways to make neural networks generalize better
Neural Networks for Machine Learning by Geoffrey Hinton [Coursera 2013] 9A Overview of ways to improve generalization 9B Limiting the size of the weights 9C Using noise as a regularizer 9D Introduction to the Bayesian Approach 9E The Bayesian interpretation of weight decay 9F MacKay's qui
From playlist Neural Networks for Machine Learning by Professor Geoffrey Hinton [Complete]
Active Noise Cancellation – From Modeling to Real-Time Prototyping
Active noise control (ANC), also known as active noise cancellation, attempts to cancel unwanted sound using destructive interference. ANC systems use adaptive digital filtering to synthesize a sound wave with the same amplitude as the unwanted signal, but with inverted phase. This video f
From playlist Real-Time Audio Prototyping
Lecture 9E : The Bayesian interpretation of weight decay
Neural Networks for Machine Learning by Geoffrey Hinton [Coursera 2013] Lecture 9E : The Bayesian interpretation of weight decay
From playlist Neural Networks for Machine Learning by Professor Geoffrey Hinton [Complete]
Lecture 9.5 — The Bayesian interpretation of weight decay [Neural Networks for Machine Learning]
Lecture from the course Neural Networks for Machine Learning, as taught by Geoffrey Hinton (University of Toronto) on Coursera in 2012. Link to the course (login required): https://class.coursera.org/neuralnets-2012-001
From playlist [Coursera] Neural Networks for Machine Learning — Geoffrey Hinton
AMMI Course "Geometric Deep Learning" - Lecture 4 (Geometric Priors II) - Joan Bruna
Video recording of the course "Geometric Deep Learning" taught in the African Master in Machine Intelligence in July-August 2021 by Michael Bronstein (Imperial College/Twitter), Joan Bruna (NYU), Taco Cohen (Qualcomm), and Petar Veličković (DeepMind) Lecture 4: Invariant function classes
From playlist AMMI Geometric Deep Learning Course - First Edition (2021)
Physics - Mechanics: Sound and Sound Waves (36 of 47) Intensity of Sound Wave 2
Visit http://ilectureonline.com for more math and science lectures! In this video I will show you how to calculate the intensity of sound wave 2.
From playlist PHYSICS MECHANICS 5: WAVES, SOUND
Stanford CS224N: NLP with Deep Learning | Winter 2019 | Lecture 8 – Translation, Seq2Seq, Attention
For more information about Stanford’s Artificial Intelligence professional and graduate programs, visit: https://stanford.io/3Cbvt8s Professor Christopher Manning & PhD Candidate Abigail See, Stanford University http://onlinehub.stanford.edu/ Professor Christopher Manning Thomas M. Sieb
From playlist Stanford CS224N: Natural Language Processing with Deep Learning Course | Winter 2019
Peter R Saulson - Vibration isolation (Passive systems)
PROGRAM: ICTS Winter School on Experimental Gravitational-Wave Physics DATES: Monday 23 Dec, 2013 - Saturday 28 Dec, 2013 VENUE: Raja Ramanna Centre for Advanced Technology, Indore PROGRAM LINK: http://www.icts.res.in/program/GWS2013 A worldwide network of detectors are currently involved
From playlist ICTS Winter School on Experimental Gravitational-Wave Physics
Foundations for Learning in the Age of Big Data II - Maria Florina Balcan
Topic: Foundations for Learning in the Age of Big Data Speaker: Maria Florina Balcan Affiliation: Carnegie Mellon University Date: May 24, 2022 Balcan-2022-05-24
From playlist Mathematics
Stanford CS234: Reinforcement Learning | Winter 2019 | Lecture 6 - CNNs and Deep Q Learning
For more information about Stanford’s Artificial Intelligence professional and graduate programs, visit: https://stanford.io/ai Professor Emma Brunskill, Stanford University http://onlinehub.stanford.edu/ Professor Emma Brunskill Assistant Professor, Computer Science Stanford AI for Hu
From playlist Stanford CS234: Reinforcement Learning | Winter 2019
Physics - Mechanics: Sound and Sound Waves (9 of 47) Decibel Scale Conversion
Visit http://ilectureonline.com for more math and science lectures! In this video I will show you how to convert from decibel to W/m^2 and vice versa.
From playlist PHYSICS MECHANICS 5: WAVES, SOUND