betse
habitat-api
| betse | habitat-api | |
|---|---|---|
| 4 | 1 | |
| 51 | 752 | |
| - | - | |
| 4.7 | 8.4 | |
| 6 months ago | over 2 years ago | |
| Python | Python | |
| BSD 2-clause "Simplified" License | MIT License |
Stars - the number of stars that a project has on GitHub. Growth - month over month growth in stars.
Activity is a relative number indicating how actively a project is being developed. Recent commits have higher weight than older ones.
For example, an activity of 9.0 indicates that a project is amongst the top 10% of the most actively developed projects that we are tracking.
betse
- New neural network architecture inspired by neural system of a worm
-
What ever happened to the first cryogenically frozen humans?
Jeanne Louise Calment lived 122 years and 164 days [1]. Doubling the lifespan, 240+ years, is most certainly not possible, not reasonable, using diets, exercises, and so forth: if it were, we would have already been there. Even if we could push the body using current technology, no one will want to live 100+ years (from age 70 to 160+) as an old person, being in pain constantly, fighting all kinds of cancers.
Therefore, the only way I can see a lifespan push, not only x2, but x10, or even x100 (10,000 years—once you get x3/x4, it probably scales trivially) is through 100% organ regeneration and 100% programmatic control over the morphospace. Broke an arm? Amputate the limb and grow another one back, your cells already did it before. Liver cancer? Regrow another liver. Heart issues? Make another heart. Spend all the years above 35 as a perpetual 35 year old, eventually in the bodyshape of Chris Hemsworth/Margot Robbie (to keep the examples in Australia). This scientific fancy is somehow grounded in the mind-enlarging perspectives coming from Dr. Michael Levin's lab [2]. Personally, I believe enough in their thesis, programmatic control over cells, that I started learning about their work, BETSE, Bio Electric Tissue Simulation Engine [3], and try to build on top a BioElectric Simulation Orchestrator, BESO [4]. Most probably, however, we won't see 100% human organ regeneration in our regular lifetimes, but never say never.
[1] https://en.wikipedia.org/wiki/Jeanne_Calment
[2] Speaking with Cells: the Electrical Future of Regenerative Medicine with Dr. Michael Levin https://www.youtube.com/watch?v=RzGaakopAKU
[3] https://github.com/betsee/betse
[4] https://github.com/daysful/beso
- Betse: Bio Electric Tissue Simulation Engine
- From Wound Healing to Regeneration
habitat-api
-
DD-PPO, TD3, SAC: which is the best?
Code for https://arxiv.org/abs/1911.00357 found: https://github.com/facebookresearch/habitat-api
What are some alternatives?
CfC - Closed-form Continuous-time Neural Networks
simglucose - A Type-1 Diabetes simulator implemented in Python for Reinforcement Learning purpose
beso - BioElectric Simulation Orchestrator
panda-gym - Set of robotic environments based on PyBullet physics engine and gymnasium.
holodeck - High Fidelity Simulator for Reinforcement Learning and Robotics Research.
MATLAB-Simulink-Challenge-Project-Hub - This MATLAB and Simulink Challenge Project Hub contains a list of research and design project ideas. These projects will help you gain practical experience and insight into technology trends and industry directions.
PyGame-Learning-Environment - PyGame Learning Environment (PLE) -- Reinforcement Learning Environment in Python.
DI-sheep - 羊了个羊 + 深度强化学习(Deep Reinforcement Learning + 3 Tiles Game)
ai-robot-hand-with-raspberry-pi - A robotics hand that mimics human hands using Computer Vision.
ai2thor-rearrangement - 🔀 Visual Room Rearrangement
agents - TF-Agents: A reliable, scalable and easy to use TensorFlow library for Contextual Bandits and Reinforcement Learning.
deepbots - A wrapper framework for Reinforcement Learning in the Webots robot simulator using Python 3.