Thanks a lot. We hope that in 10 years these robots can be deployed fully autonomously in hazardous real-world environments to assist humans or even completely remove them from harms way.

We are very happy to hear that we can inspire people all round the world. No control methods works out of the box. There is always a lot of tuning and engineering work required to successfully bridge the sim2real gap.

These are indeed very exciting research topics. Check our channel for updates about coordinated robot collaboration.

Absolutely agree! Navigation is the next big step that we try to tackle.

They do not have force sensors on their feet because the repeated impacts will most likely break them. However, we can measure the torque at the actuators, which allows to estimate the interaction force. But you are probably right: if the robot would also have a sense of touch, it would understand its surroundings even better.

The reference trajectories come from a model-based optimization method. In our case we have used TAMOLS (arxiv.org/abs/2206.14049), but it could be substituted with any other method aswell.

The TO method, unfortunately, is not open.source because it depends on ANYmal research. We currently considering to open-source the RL part independently.

In this work, we have combined model-based with model-free control. While this does combine the advantages of both methods, it also merges some of their disadvantages, one of them being the fixed gait. This assumption reduces the number of potential motions but also ensures that the learned behaviors transfer well to reality.

@@leggedrobotics Fair, and I am just speculating. But let me ask, is this the same movement system as other popular 'dogs', like Spot? If no, what are they (Boston Dynamics) doing differently? Because their robots definitely seem... well, more agile to be honest. Haven't seen Spot in a while though.

@@Ree1981 Most quadrupedal robots, including Spot, are deployed with a gait pattern called "trot". This type of foot alternation can typically be observed with horses, zebras, and deers when they target intermediate fast locomotion velocities. It is a very stable gait that does not requite large lateral or vertical base motions. Because of these properties, it also emerges with learning-based methods, even when not specifically enforced (in our case, however, we do enforce it). Spot's legs are are much lighter and longer than those of ANYmal. This allows for fast gait cycles and large steps, without moving a large amount of intertia. Think, for example, about a pitbull (ANYmal) and a gazell (Spot). Both animals have specialized locomotion behaviors based on their kinematic structure and dynamic properties.

@@leggedrobotics Ok, so it could be that my opinion was spot-on (pun intended). Human intervention could be slowing your progress. Because let's face it, ANYmal looks slow and clunky by today's standards. Consider a new approach.

Our robots don't harm humans, animals, or other robots ;)

@@leggedrobotics A robot may not injure a human being or, through inaction, allow a human being to come to harm. :)

@@peterlustig2048Based on that rule, why doesn’t ANYmal try and grab a cigarette from any smoking human it encounters? :)

@@gf2e lol, love it! The second law states: A robot must obey the orders given it by human beings except where such orders would conflict with the First Law. So I guess you still have a vaild point. It is really hard to state what we want robots to do :)