×
![]()
Introducing a context-based framework for comprehensively evaluating the social and ethical risks of AI systems
Introducing a context-based framework for comprehensively evaluating the social and ethical risks of AI systems
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
Robots are great specialists, but poor generalists. Typically, you have to train a model for each task, robot, and environment. Changing a single variable often requires starting from scratch. But what if we could combine the knowledge across robotics and create a way to train a general-purpose robot?
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New AI tool classifies the effects of 71 million ‘missense’ mutations.
New tool helps watermark and identify synthetic images created by Imagen
New tool helps watermark and identify synthetic images created by Imagen
New tool helps watermark and identify synthetic images created by Imagen
New tool helps watermark and identify synthetic images created by Imagen
New tool helps watermark and identify synthetic images created by Imagen
New tool helps watermark and identify synthetic images created by Imagen
New tool helps watermark and identify synthetic images created by Imagen
New tool helps watermark and identify synthetic images created by Imagen
Robotic Transformer 2 (RT-2) is a novel vision-language-action (VLA) model that learns from both web and robotics data, and translates this knowledge into generalised instructions for robotic control.
Robotic Transformer 2 (RT-2) is a novel vision-language-action (VLA) model that learns from both web and robotics data, and translates this knowledge into generalised instructions for robotic control.
Robotic Transformer 2 (RT-2) is a novel vision-language-action (VLA) model that learns from both web and robotics data, and translates this knowledge into generalised instructions for robotic control.
Robotic Transformer 2 (RT-2) is a novel vision-language-action (VLA) model that learns from both web and robotics data, and translates this knowledge into generalised instructions for robotic control.