Extrapolations and Crowdfunded Research (Experiment) | Two Minute Papers #44

Two Minute Papers · Beginner ·📄 Research Papers Explained ·10y ago

Key Takeaways

The video discusses extrapolation, a technique used to forecast future values based on past data, and applies it to a real-world example of crowdfunded research, using linear, superlinear, and sublinear extrapolation methods.

Full Transcript

dear fellow Scholars this is 2minute papers with Caro what is extrapolation we hear the term a lot so let's try to learn what's behind it despite the complicated definitions that are out there extrapolation basically means continuing lines a good example is when we have data for something from the last few days or years and would like to have a forecast for the future we'll jump right into an example just give me a second to build this up it's going to make sense in the end I promise so in many fields of science it is really difficult to get research projects funded experiment is a cool new startup that is trying to accelerate progress by crowdsourcing it it doesn't get simpler than this system scientists pitch their research project plan and kind-hearted people pledge a one-time donation to help their cause it is like Kickstarter for research some of the newer funded projects include growing food in space developing an open protocol for insulin production and of course a mandatory Cat Project that includes sequencing the Genome of rare mutations crowdfunding research is such a terrific idea and I tell you these guys are really doing it right the startup has been founded in 2012 and people pledged $52,000 that year in the next year 10 times that and they have kept a steady and quite impressive growth ever since in 2015 they raised almost $4 million for open research it's amazing okay so a nice extrapolation problem how much can they expect to raise next year in 2016 before we start we have to be extremely sure to extrapolate only if we are reasonably sure about the nature of the trends and that they won't change significantly in the near future with that out of the way let's do a linear extrapolation linear means that growth follows a straight line so we put these dots on a paper and try to to connect them with a line now we take the mathematical description of this line and substitute something in it since we have four years of data four dots we would be interested in the location of the fifth point which is the amount of raised money in 2016 so let's do it 10 the 6 is 1 million so this says that we can expect $4.2 million but let's be more optimistic and do a super linear extrapolation superlinear means that the rate of growth is not a straight line but something that is accelerating in time if this assumption is true we can expect them to raise way more $7.4 million a bit more pessimistic solution would be a sublinear extrapolation sublinear means that growth slows down in time this kind of growth is described well with for instance the logarithm function this effect is also often called the effect of diminishing returns a good example of this is the skill level of Google deep Minds artificial intelligence program that plays go as we add more and more computational resources the algorithm gets better and better at the game but after a point there's only so much one can learn therefore progress slows down and eventually gets close to stopping there are so many examples of this effect in our lives if you have some great examples of logarithmic growth let me know in the comment section I'll include the best ones in the video description box according to this logarithm we can expect the company to raise less than the previous estimation $3.1 million next year sorry guys a common Pitfall in popular media is that the mathematically untrained Minds almost always assume linear growth due to its Simplicity this can lead to hilariously wrong results if you would extrapolate the size of the belly of a pregnant woman after 9 months your conclusion would be run because she's going to explode whereas we know that a baby is going to be born and she is going to get back in shape if I had zero wives yesterday and it's my wedding day today I will sure as hell have a couple dozen wives by next month many things are inherently nonlinear and doing a simple linear extrapolation often doesn't do justice to the problem at hand bear in mind that there are many different ways to connect a bunch of dots let's try to find out why we had widely varying results this is due to the fact that we only had four samples that means four dots if I plot these possible functions that we've been talking about we get the following it seems that the further we go the more they diverge however in this case if we have data only between zero and one for instance there is very little difference between a wild exponential function and a very conservative square root based growth you can also Imagine your logarithm here the more dots we have over a greater period of time the more we can distinguish the nature of our growth and an educated mind has to take into consideration that many phenomena are inherently nonlinear if you catch someone doing a linear extrapolation always ask ask are you sure that the process your modeling is indeed linear and do you have enough data to prove that that's all for today thanks for watching and for your generous support and I'll see you next time

Original Description

What is extrapolation? Extrapolation basically means continuing lines (or connecting dots, if you like this intuition better). A good example is when we have data for something from the last few days or years, and would like to have a forecast for the future. We will do some linear and nonlinear extrapolations (and learn what they mean) and try to find out the amount of money Experiment will raise for open research. Experiment is a cool new startup that is trying to accelerate progress in research by crowdsourcing it. ______________________ Logarithmic growth examples from the comments: - athletic training - at first, you make great improvements, then as you approach the limits of your endurance, progress slows down, and eventually stops (Morten Eriksen), - The approximate number of Olympic records on the men's 100 m sprint (RelatedGiraffe), - Bacterial growth. At first, there is a lot of sugar to feed bacteria but there simply aren't that many bacteria and they split as fast as they possibly can, roughly doubling each time step. But eventually the limits of the available sugar become apparent and newly born bacteria either don't find enough nutrition to split again or they outright starve. Inevitably you run into a balance where about as many bacteria die as are born and thus the population growth runs flat (Kram). Subscribe if you would like to see more of these! - http://www.youtube.com/subscription_center?add_user=keeroyz Experiment, crowdsourcing research: https://experiment.com/ Links to Wolfram|Alpha to reproduce the experiments ( Linear fit: http://www.wolframalpha.com/input/?i=linear+fit+52700,+527197,+766924,+3856542 Quadratic fit: http://www.wolframalpha.com/input/?i=quadratic+fit+52700,+527197,+766924,+3856542 Logarithmic fit: http://www.wolframalpha.com/input/?i=logarithmic+fit+52700,+527197,+766924,+3856542 Plot ALL the functions! http://www.wolframalpha.com/input/?i=plot+sqrt%28x%29+and+x+and+x%5E2+and+e%5Ex-2+where+x+%3D+0..5+y%3D0..4 One mo
Watch on YouTube ↗ (saves to browser)
Sign in to unlock AI tutor explanation · ⚡30

Playlist

Uploads from Two Minute Papers · Two Minute Papers · 50 of 60

1 Fluid Simulations with Blender and Wavelet Turbulence | Two Minute Papers #1
Fluid Simulations with Blender and Wavelet Turbulence | Two Minute Papers #1
Two Minute Papers
2 Capturing Waves of Light With Femto-photography | Two Minute Papers #2
Capturing Waves of Light With Femto-photography | Two Minute Papers #2
Two Minute Papers
3 Artificial Neural Networks and Deep Learning | Two Minute Papers #3
Artificial Neural Networks and Deep Learning | Two Minute Papers #3
Two Minute Papers
4 Blender Rendering - Top 7 LuxRender Features
Blender Rendering - Top 7 LuxRender Features
Two Minute Papers
5 Simulating Breaking Glass | Two Minute Papers #4
Simulating Breaking Glass | Two Minute Papers #4
Two Minute Papers
6 Time Lapse Videos From Community Photos | Two Minute Papers #5
Time Lapse Videos From Community Photos | Two Minute Papers #5
Two Minute Papers
7 AI Learns Van Gogh's Art
AI Learns Van Gogh's Art
Two Minute Papers
8 Hydrographic Printing | Two Minute Papers #7
Hydrographic Printing | Two Minute Papers #7
Two Minute Papers
9 Announcing LuxRender 1.5
Announcing LuxRender 1.5
Two Minute Papers
10 Digital Creatures Learn To Walk | Two Minute Papers #8
Digital Creatures Learn To Walk | Two Minute Papers #8
Two Minute Papers
11 Manipulating Photorealistic Renderings | Two Minute Papers #9
Manipulating Photorealistic Renderings | Two Minute Papers #9
Two Minute Papers
12 Adaptive Fluid Simulations | Two Minute Papers #10
Adaptive Fluid Simulations | Two Minute Papers #10
Two Minute Papers
13 Building Bridges With Flying Machines | Two Minute Papers #11
Building Bridges With Flying Machines | Two Minute Papers #11
Two Minute Papers
14 Reconstructing Sound From Vibrations | Two Minute Papers #12
Reconstructing Sound From Vibrations | Two Minute Papers #12
Two Minute Papers
15 Creating Photographs Using Deep Learning | Two Minute Papers #13
Creating Photographs Using Deep Learning | Two Minute Papers #13
Two Minute Papers
16 Adaptive Cloth Simulations | Two Minute Papers #14
Adaptive Cloth Simulations | Two Minute Papers #14
Two Minute Papers
17 Synthesizing Sound From Collisions | Two Minute Papers #15
Synthesizing Sound From Collisions | Two Minute Papers #15
Two Minute Papers
18 Metropolis Light Transport | Two Minute Papers #16
Metropolis Light Transport | Two Minute Papers #16
Two Minute Papers
19 3D Printing a Glockenspiel | Two Minute Papers #17
3D Printing a Glockenspiel | Two Minute Papers #17
Two Minute Papers
20 Modeling Colliding and Merging Fluids | Two Minute Papers #18
Modeling Colliding and Merging Fluids | Two Minute Papers #18
Two Minute Papers
21 Recurrent Neural Network Writes Music and Shakespeare Novels | Two Minute Papers #19
Recurrent Neural Network Writes Music and Shakespeare Novels | Two Minute Papers #19
Two Minute Papers
22 Gradients, Poisson's Equation and Light Transport | Two Minute Papers #20
Gradients, Poisson's Equation and Light Transport | Two Minute Papers #20
Two Minute Papers
23 Real-Time Facial Expression Transfer | Two Minute Papers #21
Real-Time Facial Expression Transfer | Two Minute Papers #21
Two Minute Papers
24 Automatic Lecture Notes From Videos | Two Minute Papers #22
Automatic Lecture Notes From Videos | Two Minute Papers #22
Two Minute Papers
25 Be a Part of Two Minute Papers on Patreon!
Be a Part of Two Minute Papers on Patreon!
Two Minute Papers
26 Recurrent Neural Network Writes Sentences About Images | Two Minute Papers #23
Recurrent Neural Network Writes Sentences About Images | Two Minute Papers #23
Two Minute Papers
27 How Does Deep Learning Work? | Two Minute Papers #24
How Does Deep Learning Work? | Two Minute Papers #24
Two Minute Papers
28 Cryptography, Perfect Secrecy and One Time Pads | Two Minute Papers #25
Cryptography, Perfect Secrecy and One Time Pads | Two Minute Papers #25
Two Minute Papers
29 Terrain Traversal with Reinforcement Learning | Two Minute Papers #26
Terrain Traversal with Reinforcement Learning | Two Minute Papers #26
Two Minute Papers
30 Multiple-Scattering Microfacet BSDFs with the Smith Model
Multiple-Scattering Microfacet BSDFs with the Smith Model
Two Minute Papers
31 Google DeepMind's Deep Q-Learning & Superhuman Atari Gameplays | Two Minute Papers #27
Google DeepMind's Deep Q-Learning & Superhuman Atari Gameplays | Two Minute Papers #27
Two Minute Papers
32 Are We Living In a Computer Simulation? | Two Minute Papers #28
Are We Living In a Computer Simulation? | Two Minute Papers #28
Two Minute Papers
33 Artificial Superintelligence [Audio only] | Two Minute Papers #29
Artificial Superintelligence [Audio only] | Two Minute Papers #29
Two Minute Papers
34 Automatic Parameter Control for Metropolis Light Transport | Two Minute Papers #30
Automatic Parameter Control for Metropolis Light Transport | Two Minute Papers #30
Two Minute Papers
35 Randomness and Bell's Inequality [Audio only] | Two Minute Papers #31
Randomness and Bell's Inequality [Audio only] | Two Minute Papers #31
Two Minute Papers
36 OpenAI - Non-profit AI company by Elon Musk and Sam Altman
OpenAI - Non-profit AI company by Elon Musk and Sam Altman
Two Minute Papers
37 How Do Genetic Algorithms Work? | Two Minute Papers #32
How Do Genetic Algorithms Work? | Two Minute Papers #32
Two Minute Papers
38 Painting with Fluid Simulations | Two Minute Papers #33
Painting with Fluid Simulations | Two Minute Papers #33
Two Minute Papers
39 Peer Review #1 [Audio only] | Two Minute Papers
Peer Review #1 [Audio only] | Two Minute Papers
Two Minute Papers
40 Neural Programmer-Interpreters Learn To Write Programs | Two Minute Papers #34
Neural Programmer-Interpreters Learn To Write Programs | Two Minute Papers #34
Two Minute Papers
41 9 Cool Deep Learning Applications | Two Minute Papers #35
9 Cool Deep Learning Applications | Two Minute Papers #35
Two Minute Papers
42 Designing Cities and Furnitures With Machine Learning | Two Minute Papers #36
Designing Cities and Furnitures With Machine Learning | Two Minute Papers #36
Two Minute Papers
43 Designing 3D Printable Robotic Creatures | Two Minute Papers #37
Designing 3D Printable Robotic Creatures | Two Minute Papers #37
Two Minute Papers
44 3D Printing Objects With Caustics | Two Minute Papers #38
3D Printing Objects With Caustics | Two Minute Papers #38
Two Minute Papers
45 Interactive Editing of Subsurface Scattering | Two Minute Papers #39
Interactive Editing of Subsurface Scattering | Two Minute Papers #39
Two Minute Papers
46 Simulating Viscosity and Melting Fluids | Two Minute Papers #40
Simulating Viscosity and Melting Fluids | Two Minute Papers #40
Two Minute Papers
47 What Do Virtual Objects Sound Like? | Two Minute Papers #41
What Do Virtual Objects Sound Like? | Two Minute Papers #41
Two Minute Papers
48 How DeepMind Conquered Go With Deep Learning (AlphaGo) | Two Minute Papers #42
How DeepMind Conquered Go With Deep Learning (AlphaGo) | Two Minute Papers #42
Two Minute Papers
49 Breaking Deep Learning Systems With Adversarial Examples | Two Minute Papers #43
Breaking Deep Learning Systems With Adversarial Examples | Two Minute Papers #43
Two Minute Papers
Extrapolations and Crowdfunded Research (Experiment) | Two Minute Papers #44
Extrapolations and Crowdfunded Research (Experiment) | Two Minute Papers #44
Two Minute Papers
51 Biophysical Skin Aging Simulations | Two Minute Papers #45
Biophysical Skin Aging Simulations | Two Minute Papers #45
Two Minute Papers
52 What is Impostor Syndrome? | Two Minute Papers #46
What is Impostor Syndrome? | Two Minute Papers #46
Two Minute Papers
53 Should You Take the Stairs at Work? (For Weight Loss) | Two Minute Papers #47
Should You Take the Stairs at Work? (For Weight Loss) | Two Minute Papers #47
Two Minute Papers
54 Artistic Manipulation of Caustics | Two Minute Papers #48
Artistic Manipulation of Caustics | Two Minute Papers #48
Two Minute Papers
55 Deep Learning Program Learns to Paint | Two Minute Papers #49
Deep Learning Program Learns to Paint | Two Minute Papers #49
Two Minute Papers
56 Interactive Photo Recoloring | Two Minute Papers #50
Interactive Photo Recoloring | Two Minute Papers #50
Two Minute Papers
57 How To Get Started With Machine Learning? | Two Minute Papers #51
How To Get Started With Machine Learning? | Two Minute Papers #51
Two Minute Papers
58 Awesome Research For Everyone! - Two Minute Papers Channel Trailer
Awesome Research For Everyone! - Two Minute Papers Channel Trailer
Two Minute Papers
59 10 More Cool Deep Learning Applications | Two Minute Papers #52
10 More Cool Deep Learning Applications | Two Minute Papers #52
Two Minute Papers
60 How DeepMind's AlphaGo Defeated Lee Sedol | Two Minute Papers #53
How DeepMind's AlphaGo Defeated Lee Sedol | Two Minute Papers #53
Two Minute Papers

The video teaches viewers about extrapolation techniques, including linear, superlinear, and sublinear methods, and applies them to a real-world example of crowdfunded research, highlighting the importance of considering nonlinear growth and diminishing returns.

Key Takeaways
  1. Define extrapolation and its importance in data analysis
  2. Apply linear extrapolation to a real-world example
  3. Apply superlinear and sublinear extrapolation to the same example
  4. Compare and contrast the results of different extrapolation methods
  5. Consider the limitations and potential pitfalls of linear extrapolation
💡 Many phenomena are inherently nonlinear, and assuming linear growth can lead to incorrect conclusions.

Related Reads

📰
I Spent Weeks Looking for a Research Gap Before I Realized I Was Searching the Wrong Way
Learn how to effectively find research gaps by changing your approach, a crucial skill for AI researchers and academics
Medium · AI
📰
ICMI 2026 Reviews [D]
Learn how to interpret ICMI 2026 reviews and improve your paper's acceptance chances
Reddit r/MachineLearning
📰
Workshop submission for main conference paper under review [D]
Learn how to navigate submitting a paper to a non-archival workshop before the final decision of a main conference like ECCV
Reddit r/MachineLearning
📰
Kept context-switching between arxiv, OpenReview, GitHub, and HuggingFace for every paper, so I built this. Chrome extension + website with everything inline, plus citation graph + SPECTER2 neighbors. 3M papers, free, feedback welcome [P]
Streamline your research with a new Chrome extension and website that integrates 3M papers from arxiv, OpenReview, GitHub, and HuggingFace, including citation graphs and SPECTER2 neighbors, and provide feedback to improve it
Reddit r/MachineLearning
Up next
Indians Under House Arrest in America? 😱 Immigration Crisis Explained | SumanTV Classroom
SumanTV Classroom
Watch →