If you are a ROS developer/user and you blog about it, ROS wants those contributions on this page ! All you need for that to happen is:

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• make your ROS related posts tagged with any of the following categories: "ROS", "R.O.S.", "ros", "r.o.s."

For security reasons, html iframe, embed, object, javascript will be stripped out. Only Youtube videos in object and embed will be kept.

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Blogs should be related to ROS but that does not mean they should be devoid of personal subjects and opinions : those are encouraged since Planet ROS is a chance to know more about ROS developers.

Posts can be positive and promote ROS, or constructive and describe issues but should not contain useless flaming opinions. We want to keep ROS welcoming :)

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Thanks to new contributor, we have documentation of, and several options for, axis conventions in pyspacemouse not yet released to pypi, but please try it out (you can pip install directly from github!) and let me know what you think.

Longer term, the plan is to change the default convention to HID, because the LEGACY convention is, frankly, insane, and I don’t want all users to have to “fix it” on their own.

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Hello fellow ROS users, maintainers, contributors and anyone else who may be passing by.

Due to a recent uptick in LLM-authored pull requests, the ROS PMC has elected to extend the upstream OSRF policy on the use of generative tools to help provide some boundaries/guidelines on the use of these tools. These tools and technologies are constantly changing, so this isn’t intended to serve as a permanent policy, but rather it is to provide a framework for how to interact on ROS-related projects.

The TLDR, because there are a lot of words below: Feel free to use the tools to build, explore, and understand software (as many of the maintainers also do), but when it comes time to interact on Discourse, Zulip, or Github, try to leave the LLM-centric text behind. A large component of open source software is about building/collaborating with people, and we would generally prefer to interact with people rather than an LLM-proxy.

Maintainer time is a finite and constrained resource. While generative AI tools can be useful development assistants, submitting unverified Large Language Model (LLM) output shifts the engineering, debugging, and verification work onto project maintainers.

This document establishes the rules for interacting with ROS project repositories when using AI tools. It serves as an extension of the upstream OSRF Policy on the Use of Generative Tools in Contributions. While the upstream policy defines the legal, IP, and attribution requirements for AI-generated code, these rules define the quality and behavioral standards required to protect maintainer bandwidth.

The Author Ownership Rule

The upstream OSRF policy states that contributors must have the right to sign the Developer Certificate of Origin (DCO). Operationally, this means you are the sole owner of, and are fully responsible for, the code you submit.

• Do not use maintainers as an LLM validation service. If a maintainer points out a bug, architectural issue, or syntax error in your PR, you may not simply paste that feedback back into an LLM and copy-paste the unverified output as a response.

• You must understand every line of code you submit. If a maintainer asks why a specific technical choice was made, responding with “an LLM generated this” or providing a generic, AI-synthesized explanation is unacceptable. You must be able to defend the technical merits of your implementation yourself.

• Maintainers want to engage with you, the author of the proposed changes. Maintainers want to understand why you want to make the change and why you want to implement it the way the PR proposes. Maintainers do not want to talk to your chatbot.

Zero-Tolerance for Hallucinated API/Dependency Usage

LLMs frequently hallucinate APIs, configuration parameters, or entire library features, especially given the fast-moving nature of ROS releases and underlying middleware (DDS, Zenoh, rclcpp, rclpy, etc.).

• Any PR that introduces non-existent APIs, impossible configuration keys, or broken logic due to LLM hallucinations will be closed immediately without review.

• Repeat offenses will result in a temporary or permanent block from the organization’s repositories.

Compliance with Upstream Disclosure & Attribution

The upstream OSRF policy explicitly requires that the use of generative tools be disclosed if they created a material part of the contribution. We enforce this strictly on GitHub:

• If an LLM was used to generate structural code, tests, or documentation boilerplate, state it clearly in the PR description.

• Do not LLM dump to generate your PR description. Paragraphs filled with generic AI phrasing (e.g., “This PR enhances the efficiency of the codebase by utilizing modern design patterns and optimizing asynchronous paradigms…”) will be rejected. Write a concise, human-authored summary explaining exactly what changed and why.

Enforcement and Maintainer Recourse

To maintain the health of the project, maintainers have full discretion to handle low-effort, AI-driven contributions efficiently:

• If an issue or PR is clearly an unverified LLM dump (e.g., containing generic AI comments, formatting that violates project style guides, contains a poorly formatted description pasted directly from an LLM, or obviously broken logic), maintainers are authorized to close the PR immediately.

• If a contributor responds to code review feedback using obvious, unedited LLM-generated text that fails to address the underlying engineering critique, maintainers are authorized to close the PR immediately.

• If the contributor fails to respond to reviewer questions or feedback within a reasonable timeframe (e.g. within a week), reviewers may close the PR without further review.

• If a contributor continues to behave in an unproductive way through repeated submission of inappropriate LLM-dump issues or PRs, repeated copy-and-pasting of LLM-dump comments, or similar, maintainers are authorized to temporarily or permanently block that user from the organization’s repositories.

Guidelines for Responsible AI Use in ROS

If you want to use an LLM to help you successfully contribute to ROS, adhere to the following workflow:

1. Confirm that the issue is still valid and that any proposed solution is still preferred. Start a conversation on the issue thread to ensure maintainers agree with the approach. Opening PRs for stale or invalid issues simply because an AI bot identified them creates unnecessary overhead for maintainers and is strongly discouraged.

2. Run the code locally. Verify it compiles, passes linting, and passes all relevant tests before opening a PR.

3. Before hitting “Submit,” read through your own diff line-by-line. Remove any redundant logic, overly verbose AI-generated comments, or structural weirdness introduced by the model.

4. Explain your changes in plain technical language. If you can’t describe the change yourself, you aren’t ready to submit it.

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The group is not meeting today (2026-06-29) due to lack of available members!

Please come and join us for this coming meeting at Mon, Jul 13, 2026 4:00 PM UTC→Mon, Jul 13, 2026 5:00 PM UTC, where we will be editing the first draft of the Logging and Observability guide, generated by AI. The AI used the skeleton of the guide from the previous session and transcripts from all meeting recordings to generate a guide. The group will edit this starting point together in the coming session.

Please note: as this session will be a lot of reading and editing, the group does not plan to record the session.

Last session, we created the skeleton for the guide above, as we have been discussing Logging and Observability tips and best practices over the course of several months. Once the guide has been fully written, previous guest speakers will be invited to review it before it’s published. If you’re interested in watching the previous session, the meeting recording is available on YouTube.

The meeting link for next meeting is here, and you can sign up to our calendar or our Google Group for meeting notifications or keep an eye on the Cloud Robotics Hub.

Hopefully we will see you there!

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Hi ROS community,

I’m working on ClawsJoy Robotics, a proposal for a standard interface between LLM-based cognitive systems and ROS/2 robots. The core idea: any LLM outputs an action, any robot implements these standard topics.

The Problem

Every robotics company maps “pick up the cup” to different ROS/2 interfaces:

• Company A: custom service /manipulation/pick

• Company B: action server /grasp_object

• Company C: proprietary SDK

There’s no standard way for an LLM agent to tell a robot what to do.

The Proposal: 12 Standard Motion Primitives

navigate_to → /base/cmd_vel (geometry_msgs/Twist)
move_arm → /arm/joint_trajectory (trajectory_msgs/JointTrajectory)
move_base → /base/cmd_vel (geometry_msgs/Twist)
grasp → /gripper/command (std_msgs/Float32, 0=close 1=open)
release → /gripper/command (std_msgs/Float32)
push → /base/cmd_vel (geometry_msgs/Twist)
look_at → camera PTZ control
detect_objects → /perception/objects (vision_msgs/Detection3DArray)
get_pose → /base/odom + /arm/joint_states
speak → /speech/tts (std_msgs/String)
play_gesture → /arm/joint_trajectory (pre-defined trajectories)
wait → no topic (sleep)
emergency_stop → /safety/estop (std_msgs/Bool)
Demo Output

Natural language → task execution (mock mode):
[Result]: Task completed in 6 steps
▸ look_at → table
▸ detect_objects → cup detected
▸ navigate_to → table
▸ move_arm → grasp position
▸ grasp → cup_01
▸ speak → “已拿到水杯” (cup fetched)

[Result]: Task completed in 6 steps
▸ navigate_to → waypoint_1
▸ look_at → front
▸ speak → “waypoint_1 clear”
▸ navigate_to → waypoint_2
▸ look_at → left
▸ speak → “waypoint_2 clear”
Integration Checklist

To integrate a robot with ClawsJoy Robotics:

1. Arm: publish /arm/joint_states, subscribe /arm/joint_trajectory

2. Gripper: subscribe /gripper/command (Float32, 0=close 1=open)

3. Base: subscribe /base/cmd_vel, publish /base/odom

4. Camera: publish /camera/rgb, /camera/depth

5. Perception: publish /perception/objects

6. Speech: subscribe /speech/tts

7. Safety: subscribe /safety/estop

Then set mock_mode=False and run.

Code

https://github.com/your-org/clawsjoy_robotics

12 primitives defined in motion_primitives.yaml. Full topic mapping in bridge/ros2_bridge.py. Task planner in planner/planner.py.

Questions for the community

1. Are these 12 primitives sufficient, or should we add/remove some?

2. Is trajectory_msgs/JointTrajectory the right interface for move_arm, or should we use ROS/2 Actions?

3. Should we adopt the existing ros2_control interfaces instead of defining new topics?

4. Is this worth standardizing, or is every robot too different?

Looking forward to feedback.

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If you’re a robotics engineer, you’ve probably lost hours to URDF generation.
Not because the robot is complex but because the tooling is.

Renaming mates. Fixing joint axes. Recreating reference frames. Starting over because the CAD came from the “wrong” software.

I got tired of that workflow, so I built Jointly.
Upload a STEP assembly then get a draft URDF with inferred joints, inertia, collision meshes, and a live 3D preview.

It’s not magic , you’ll still review the result. But it turns hours of manual work into a couple of minutes.

I’d love to test it on real-world assemblies. If you have a CAD file that breaks your current exporter, Try it Now

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As shared in a lightning talk at ROSConFr: I have finally completed and “clauded” a comprehensive VS Code extension for ROS 2 development: a unified explorer, live parameter tuner, service/topic/action caller, log viewer, and syntax highlighting for interface files.

My favorite features of the extension, among others:

• Dynamically changing node ROS parameters at runtime via a YAML panel and comparing live params vs. edits: very handy for tuning PIDs, covariances, etc. Possibility to edit an existing params yaml file, inject missing parameters or view the all available parameters
• Displaying the logs of a namespace-filtered node in the output section of the IDE: useful while tuning a single set of nodes whose logs would otherwise be lost in a single launch command.
• Sending topics, services, or actions at runtime with predefined templates and QoS definitions.
• … plenty of others! I invite you to test it or check out the README section.

The main structure of the package is quite simple: usual ROS 2 CLIs are used in virtual shells to perform the functions, so no rclpy dependencies are required.

Available on:

GitHub (to install locally from the .vsix file, and for developers to edit, compile, etc.): GitHub - Tanneguydv/ros2-dev-suite: A comprehensive VS Code extension for ROS 2 development · GitHub

Visual Studio Marketplace (to directly install the extension from the IDE): ROS 2 Dev Suite - Visual Studio Marketplace

This package is a child of GitHub - ErickKramer/nvim-ros2: nvim-ros2 is a simple lua plugin that adds useful features to enhance your development workflow while developing ROS 2 modules. · GitHub , incorporating the latest pull request by Thibault Cozic for workspace navigation, ROS 2 tuner, etc. As I do not use Neovim, these features have been adapted to VS Code.

Some Screenshots:

Parameter tuning

Topic sender

Action caller

Service caller and yaml details (on mouse contextual window)

Logging filter for Output section of IDE

Dedicated notification of selected dying node

Filter left panel display by namespace

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All three ROS 2 distros are now native on Homebrew-macOS:

brew tap idesign0/ros2

brew install ros2-humble
brew install ros2-jazzy
brew install ros2-kilted

One tap to get ROS 2 Jazzy with full simulation and robotics stack support:

Gazebo (gz-sim8) — Gazebo Harmonic simulation out of the box
ros2_control — Hardware abstraction & controllers
MoveIt 2 — Motion planning
Nav2 — Autonomous navigation

No Docker. No VMs. Native macOS.

And the best part? These aren’t one-time snapshots — they stay in sync with upstream and will keep getting updated as the ecosystem evolves.

What’s next? I’ve been quietly collecting -Werror flag failures from Apple Clang across all three distros. Fixing them upstream should meaningfully improve code quality across the stack.

Want to try MoveIt 2 or TurtleBot4 tutorials on macOS? I’ve patched them for all available distros:

TurtleBot4 tutorials (Jazzy): https://lnkd.in/e2ZXMXBn
MoveIt 2 tutorials (Jazzy): https://lnkd.in/eWwNCT-G

Project Links:
Ros2_macos repo: https://lnkd.in/ehEtTSJz
Homebrew repo: https://lnkd.in/ek5zDAQB

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Can you believe this is running ROS 2?

Sony’s Ace Robot Beats Top Table Tennis Pros in Real Matches

Sony AI’s Ace just landed on the cover of Nature — the first robot ever to beat a professional table tennis player.

Let that sink in for a second:

• It tracks a ball moving at 20 m/s with spin over 9,000 rpm
• Perceives it in 10.2 ms (event-based vision)
• Decides and swings on a 1 kHz control loop
• And returns the ball at up to 19.6 m/s

This is physical AI right at the edge of what’s possible — and we’ve been working on the ROS 2 integration and support underneath it. The fact that ROS 2 holds up in a system this demanding says a lot about where the ecosystem is heading.

Huge respect to the Sony AI team. Take a look

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Hello guys !

I made a tutorial to make your own quadruped using ros2 jazzy !

If you have any feed back I am happy to hear it

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Hi all,

rclnodejs 2.1.0 is out — and it’s a step toward making rclnodejs a web-native SDK for ROS 2: a platform for bringing ROS 2 to the browser and the modern JavaScript ecosystem. With 2.1.0, the whole package is now native ESM, so building web dashboards, teleop UIs, and browser bridges on ROS 2 feels native to today’s web tooling — with the full ROS 2 runtime still underneath whenever you need real nodes.

TL;DR — 2.1.0 makes rclnodejs native ESM end-to-end. import rclnodejs from 'rclnodejs' just works, the browser SDK (rclnodejs/web) brings ROS 2 to the web, and existing require() nodes keep running untouched — the full ROS 2 runtime is still underneath.

A web-native SDK for ROS 2

• ROS 2 on the web — reach ROS 2 from a web page with rclnodejs/web: typed APIs over WebSocket, no proxy, no codegen.
• Native ESM — first-class import and top-level await, ready for Vite/esbuild and the modern web toolchain.
• Full ROS 2 runtime underneath — real nodes, pub/sub, services, actions, parameters, lifecycle, whenever you need them.
• Backward compatible — every existing CommonJS (require) project upgrades with zero code changes.

One package, both module systems

// Modern Node / browser — ESM
import rclnodejs from 'rclnodejs';        // full ROS 2 node API
import { connect } from 'rclnodejs/web';  // typed browser SDK

// Existing CommonJS nodes — unchanged
const rclnodejs = require('rclnodejs');

Where this is heading

Each release moves rclnodejs one step closer to a typed, web-native way into ROS 2:

• 2.0.0 — a typed browser SDK (rclnodejs/web) backed by a capability runtime that exposes only what web.json declares, with HTTP call / publish for non-JS clients.
• 2.1.0 — native ESM across the whole package, so rclnodejs sits naturally alongside the rest of your web stack.

The arc: from “a Node.js client that happens to run in browsers” → “a typed, allow-listed Web SDK for ROS 2”

Try it

npm i rclnodejs

• SDK guide: web/README.md
• JS demo (no toolchain): demo/web/javascript/
• TS + Vite demo: demo/web/typescript/

Feedback welcome — especially from anyone wiring ROS 2 into web frontends.

Cheers,
Minggang

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Hi, I used to work at a robotics startup that built robotic dishwashers. (https://armstrong.ai/) And part of my job was to set up diagnostics, monitoring and alerting.

Aside from not being the most interesting part of my job, it was just plain tedious to manually set (and continually tune) thresholds for various signals, topics, etc. I frequently thought it would be nice to have a system that would automate that part of my job and now that the company has closed, I built it.

Now I have reached the point where the useful next step is real robots. The system performs well on recorded public datasets and on some production infrastructure (see below), but what I do not have yet is enough hours on a variety of real robots, doing real work.

Details are here at the Transitive Robotics website:

What it is

The system watches your robot’s topics and tells you when something is wrong. No threshold tuning, no hardcoded rules. It learns what normal looks like on your robot, then flags and reports anomalies in real time.

How to get involved

Reply to this thread or email shane@targetnode.ai. I will help you get it installed and monitored.

What you get and what I am asking for

What you get:

• Anomaly detection for free on your robot with no manual threshold tuning to maintain.

• Direct influence over the direction of the system/project. I want to know what is missing, what is confusing, and what breaks on real robots in production.

What I am asking for:

• Honest and detailed feedback

Where it has been tested

I evaluated the system against public datasets that cover real hardware faults across very different platforms. The system has been tested successfully on the following datasets:

• CASPER. A UR3e collaborative robot arm with real IMU fault data, from Cardiff University. (paper)

• PADRE, Parrot Bebop 2. Real propeller damage on a quadrotor, recorded from onboard IMUs. (paper)

• PADRE, 3DR Solo. Real propeller damage on a second quadrotor airframe, with IMU and barometer data.

• ALFA. A CarbonZ T-28 fixed-wing aircraft with real engine and actuator faults, from Carnegie Mellon University’s AirLab. (data)

• UAV-SEAD. A large set of real PX4 flights with naturally occurring state-estimation anomalies, from Istanbul Technical University. (paper)

Additionally, I am running the system on my production servers. They are not robots, per se, but they are live production systems that get used every day. Right now the system is watching CPU, memory, disk/network operations (29 signals total) all without me setting or tuning thresholds. In the last 200 hours of operation (since Tuesday, June 16, 2026) there have been no false alerts.

Thanks for checking out this post and if you have any questions, reach out to me at shane@targetnode.ai

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Sharing a small open-source project that integrates a low-cost VL53L0X Time-of-Flight sensor into the Nav2 costmap as an obstacle source, in case it’s useful to anyone working with cheap range sensors on small robots.

Pipeline

VL53L0X --I2C–> ESP32 --USB serial–> serial_bridge → sensor_msgs/Range
→ tof_to_scan → sensor_msgs/LaserScan → nav2_costmap_2d::ObstacleLayer

What’s included

• ESP32 firmware (Arduino, Pololu VL53L0X library) streaming distance over serial with sensor-disconnect recovery
• An rclpy serial-bridge node publishing sensor_msgs/Range, with a threaded reader and automatic serial reconnect
• A Range → LaserScan converter that synthesizes a configurable narrow fan from the single beam (default ±0.15 rad, 31 rays), emitting +inf for out-of-range readings so the obstacle layer can raytrace-clear
• A full Nav2 costmap config wiring the scan into local and global costmaps (marking + clearing, inf_is_valid: true)
• RViz config and a troubleshooting guide

Built and tested on ROS 2 Humble / Ubuntu 22.04. Python packages (ament_python).

Scope / limitations (up front)

This is a supplementary obstacle sensor, not a LiDAR replacement — a single narrow-FOV ToF sees one thin cone.

One thing I’d be curious about others’ experience on: raytrace clearing on a stationary base leaves residual cells at the edges of the cone, since the clearing rays never cross them. It resolves once the robot moves and the cone sweeps, but I’d be interested whether anyone has handled static-case clearing for single-beam sensors more elegantly. Widening the FOV and increasing ray count helped, but felt like a workaround.

A config gotcha that may save someone time: obstacle marking worked but clearing silently didn’t, until I set obstacle_max_range < raytrace_max_range, with raytrace_max_range equal to the sensor’s true range_max. A mismatch there breaks clearing while marking still functions, so it presents as “obstacles never disappear.”

Repo (MIT): GitHub - Arjunros/nav2-vl53l1x-obstacle-layer: Low-cost VL53L0X ToF sensor as a Nav2 obstacle layer via ESP32 · GitHub

Feedback and suggestions welcome.

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I maintain Altara, a set of MIT-licensed React components for real-time robotics telemetry (PFD, moving map, gauges, event log), and I wrote up building a small drone ground station with them that talks to MAVROS over rosbridge.

The thing I was trying to solve: I wanted a status dashboard our team could open in a browser tab and drop into our own app, rather than running a separate native GCS. So the components are embeddable and themeable rather than a standalone tool.

Writeup (the rosbridge/MAVROS wiring is the interesting part): [ Building a real-time drone ground control station in React - DEV Community ]
Live demo: [ Altara Demo ] · Source: [https://github.com/JayaSaiKishanChapparam/altara\]

If you’ve built browser dashboards for a ROS2 stack, I’d like to know what you ended up reading off your topics, and where existing tools forced you into a standalone app when you wanted something embedded.

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Hey All,

I want to present KRS Unleashed, the tool I am now developing/refactoring/extending since 1 year as part of my PhD.

Some of you might still know KRS (short for Kria Robotic Stack as originally developed by Xilinx/AMD for their Kria platform) as the toolchain developed until 2023 by the ROS 2 Hardware Acceleration Working Group · GitHub .

(Short Summary for those who don’t)

It was a proof-of-concept framework that allowed to synthesize bitstreams, create a sysroot and cross-compile application against it to create robotics applications running on KV260, KR260 (and also claimed jetson, Ultra96v2,.. but i have never tested/verified that so far). So basically the main point of it is to replace this “docker container to compile” flow with ROS 2 colcon mixin and in parallel integrate all the necessary and optional things for hardware acceleration like sysroot creation or vendor-driven bitstream synthesis in a ROS 2 command.

The flow works, but I found it really hard to use:

• long build times whenever you cleaned your build/install folders, as even the sysroot and bitstream needed to resynthesize when you just changed a variable in a package (if you know what you are doing you can keep the untouched compiled packages but its not really stable nor trivial)
• cross-references and dependency cycles made it hard to change configuration like different Vitis version, other firmware OS,..
• hard to understand what each package actually did and which ones were necessary for your task - the original guide simply copied all available packages in

Basically it wasn’t really fun to use and whenever you start with a new project, you fight cmake configurations for a while until you can start coding..

My tool refactored these individual components into 3 separate logical workspaces:

• os → for firmware and sysroot creation - allows to reuse across projects (save lots of memory space, no rebuild necessary, parallel development possible by different team)
• vitis → vendor-driven toolchain necessary to automate your “accelerator bitstream flow”. I refactored also the automation into a nice Python CLI scripted way such that I can also use the Vitis workspace and manually adjust things, but this is more a FPGA developer nice-to-have. Could also be replaced with a flow for other accelerators
• krs → lightweight integration of firmware via single package, that provides the colcon mixin integration. Further a tracetools-kernels package that allows to trace arbitrary code regions in any ROS 2 application extending ros-tracing.

You can also use any of these components in isolated areas - I use for example also vitis + os for standalone faster iteration on host code variations. It might be a little bit harder to setup for the first time, but I can iterate really fast with it (built times up to 80x faster) and the setup is the same for all projects so once you understand it, its relatively easy and doesn’t require changes all over the project but just in very small, well defined areas.

I also created a Hackster Series for the brave.

I continue to develop it, current public version is still humble but I already have an internal jazzy version which I will release once I published a new paper.

Github: GitHub - TUD-ADS/KRS-Unleashed · GitHub

Hackster Series (5 Parts): 1. Getting Started

Paper: https://ieeexplore.ieee.org/document/11231288/

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REP 2000 specifies MacOS support for CMake 3.14.4 in Humble:

This is the lowest number for the whole Humble release.

However, MacOS has this note:

" ** " means that the dependency may see multiple version changes, because the dependency uses a package manager that continually updates the dependency without a stable API.

I don’t work with MacOS myself, so I don’t know how it behaves. Is it still needed nowadays to support 3.14.4 to get full support for Humble on MacOS, or can I just ignore this and upgrade to 3.16.3 from Focal (assuming that MacOS currently uses a much newer version)?

And on the other hand: Homebrew Formulae: cmake shows CMake version 4.3.4 . Does it mean that even people building Humble on MacOS will use this version? So do I need to make sure the package also builds with this version?

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Robotic manipulation remains one of the most important research directions in embodied AI. While traditional kinematics-based controllers provide stable motion execution, they often struggle in unstructured environments where adaptability is required.

Recent advances in Reinforcement Learning (RL) have enabled robotic arms to learn task-oriented behaviors directly from interaction, making it possible to achieve robust control policies without manually designing every motion strategy.

In this project, we extend the original SO-ARM101 Isaac Lab implementation by integrating the AgileX Dual-Arm Nero Manipulator, allowing developers to quickly train and validate dual-arm RL policies using NVIDIA Isaac Lab.

Reposity

Open-source implementation:

GitHub - smalleha/isaac_so_arm101: Isaac Lab external project for SO-ARM100/101 arm robot. · GitHub

Project Structure

├── robots

│   ├── dual_nero

│   │   ├── dual_nero.py

│   │   ├── __init__.py

│   │   ├── meshes

│   │   └── urdf

│   │       └── dual_nero.urdf

├── scripts

│   ├── rl_games

│   │   ├── play.py

│   │   └── train.py

│   └── zero_agent.py

├── tasks

│   ├── __init__.py

│   └── reach

│       ├── agents

│       ├── dual_nero_joint_pos_env_cfg.py

│       ├── dual_nero_reach_env_cfg.py

│       ├── __init__.py

│       └── mdp

└── ui_extension_example.py

Key additions include:

3. Importing the Robot into Isaac Lab

3.1 Preparing the URDF

Before importing the robot into Isaac Lab, mesh references inside the URDF should be converted to relative paths.

For example:

  <link name="base_link">

    <inertial>

      <origin rpy="0 0 0" xyz="-0.0592395620981769 -0.068642440505388 0.0562764736144042"/>

      <mass value="4.46524857458863"/>

      <inertia ixx="0.0608289280191989" ixy="-2.54649959130438E-06" ixz="1.11851948046933E-07" iyy="0.0218722514454004" iyz="-0.000689477252402357" izz="0.0680524540174318"/>

    </inertial>

    <visual>

      <origin rpy="0 0 0" xyz="0 0 0"/>

      <geometry>

        <mesh filename="../meshes/base_link.dae"/>

      </geometry>

      <material name="">

        <color rgba="0.776470588235294 0.756862745098039 0.737254901960784 1"/>

      </material>

    </visual>

    <collision>

      <origin rpy="0 0 0" xyz="0 0 0"/>

      <geometry>

        <mesh filename="../meshes/base_link.dae"/>

      </geometry>

    </collision>

  </link>

This ensures that the asset loader can correctly locate mesh resources during simulation.

3.2 Creating the Robot Configuration

Next, create a robot configuration file:

isaac_so_arm101/robots/dual_nero/dual_nero.py

This file defines:

• Robot articulation properties

• Joint stiffness and damping

• Actuator configuration

• Initial joint states

• Gripper settings

The resulting DUAL_NERO_CFG object becomes the robot asset used by Isaac Lab during training.

from pathlib import Path

import isaaclab.sim as sim_utils
from isaaclab.actuators import ImplicitActuatorCfg
from isaaclab.assets.articulation import ArticulationCfg

TEMPLATE_ASSETS_DATA_DIR = Path(__file__).resolve().parent

DUAL_NERO_CFG = ArticulationCfg(
    spawn=sim_utils.UrdfFileCfg(
        fix_base=True,
        merge_fixed_joints=False,
        replace_cylinders_with_capsules=True,
        asset_path=f"{TEMPLATE_ASSETS_DATA_DIR}/urdf/dual_nero.urdf",
        activate_contact_sensors=False, # set as false while waiting for capsule implementation
        rigid_props=sim_utils.RigidBodyPropertiesCfg(
            disable_gravity=False,
            max_depenetration_velocity=5.0,
        ),
        articulation_props=sim_utils.ArticulationRootPropertiesCfg(
            enabled_self_collisions=True,
            solver_position_iteration_count=8,
            solver_velocity_iteration_count=0,
        ),
        joint_drive=sim_utils.UrdfConverterCfg.JointDriveCfg(
            gains=sim_utils.UrdfConverterCfg.JointDriveCfg.PDGainsCfg(stiffness=0, damping=0)
        ),
    ),
    init_state=ArticulationCfg.InitialStateCfg(
        rot=(1.0, 0.0, 0.0, 0.0),
        joint_pos={
                "left_joint.*": 0.0,
                "right_joint.*": 0.0,
                "left_gripper_joint.*": 0.0,  
                "right_gripper_joint.*": 0.0,  
        },
        # Set initial joint velocities to zero
        joint_vel={".*": 0.0},
    ),
    actuators={
            "arm": ImplicitActuatorCfg(
                joint_names_expr=["left_joint.*", "right_joint.*"],
                effort_limit=25.0, 
                velocity_limit=1.5,
               
                stiffness={
                    "left_joint1": 200.0, 
                    "left_joint2": 170.0,
                    "left_joint3": 120.0,
                    "left_joint4": 80.0,
                    "left_joint5": 50.0,
                    "left_joint6": 20.0,
                    "left_joint7": 10.0,
                    "right_joint1": 200.0, 
                    "right_joint2": 170.0,
                    "right_joint3": 120.0,
                    "right_joint4": 80.0,
                    "right_joint5": 50.0,
                    "right_joint6": 20.0,
                    "right_joint7": 10.0
                },
               
                damping={
                    "left_joint1": 100.0,
                    "left_joint2": 60.0,
                    "left_joint3": 70.0,
                    "left_joint4": 24.0,
                    "left_joint5": 20.0,
                    "left_joint6": 10.0,
                    "left_joint7": 5,
                    "right_joint1": 100.0,
                    "right_joint2": 60.0,
                    "right_joint3": 70.0,
                    "right_joint4": 24.0,
                    "right_joint5": 20.0,
                    "right_joint6": 10.0,
                    "right_joint7": 5,
                },
            ),
        "gripper": ImplicitActuatorCfg(
            joint_names_expr=["left_gripper_joint.*","right_gripper_joint.*"],
            effort_limit_sim=22,  # Increased from 1.9 to 2.5 for stronger grip
            velocity_limit_sim=1.5,
            stiffness=800.0,  # Increased from 25.0 to 60.0 for more reliable closing
            damping=20.0,  # Increased from 10.0 to 20.0 for stability
        ),

        },
    soft_joint_pos_limit_factor=0.9,
)

Create an init.py file inside the dual_nero directory so that Python recognizes it as a package.

4. Building the Reach Environment

Two environment configuration files are required:

tasks/reach/

├── dual_nero_joint_pos_env_cfg.py

└── dual_nero_reach_env_cfg.py

4.1 Joint Position Environment Configuration

dual_nero_joint_pos_env_cfg.py specifies:

• Controlled joints

• End-effector links

• Action spaces

• Command targets

import math

import isaaclab_tasks.manager_based.manipulation.reach.mdp as mdp
from isaaclab.utils import configclass
from isaac_so_arm101.robots import DUAL_NERO_CFG # noqa: F401   
from isaac_so_arm101.tasks.reach.dual_nero_reach_env_cfg import Dual_NeroReachEnvCfg
from isaaclab.assets.articulation import ArticulationCfg

@configclass
class Dual_Nero_ReachEnvCfg(Dual_NeroReachEnvCfg):
    def __post_init__(self):
        # post init of parent
        super().__post_init__()

        # switch robot to OpenArm
        self.scene.robot = DUAL_NERO_CFG.replace(prim_path="{ENV_REGEX_NS}/Robot",)

        # override rewards
        self.rewards.left_end_effector_position_tracking.params["asset_cfg"].body_names = ["left_gripper_base"]
        self.rewards.left_end_effector_position_tracking_fine_grained.params["asset_cfg"].body_names = [
            "left_gripper_base"
        ]
        self.rewards.left_end_effector_orientation_tracking.params["asset_cfg"].body_names = ["left_gripper_base"]

        self.rewards.right_end_effector_position_tracking.params["asset_cfg"].body_names = ["right_gripper_base"]
        self.rewards.right_end_effector_position_tracking_fine_grained.params["asset_cfg"].body_names = [
            "right_gripper_base"
        ]
        self.rewards.right_end_effector_orientation_tracking.params["asset_cfg"].body_names = ["right_gripper_base"]

        # override actions
        self.actions.left_arm_action = mdp.JointPositionActionCfg(
            asset_name="robot",
            joint_names=[
                "left_joint.*",
            ],
            scale=0.5,
            use_default_offset=True,
        )

        self.actions.right_arm_action = mdp.JointPositionActionCfg(
            asset_name="robot",
            joint_names=[
                "right_joint.*",
            ],
            scale=0.5,
            use_default_offset=True,
        )
        # override command generator body
        # end-effector is along z-direction
        self.commands.left_ee_pose.body_name = "left_gripper_base"
        self.commands.right_ee_pose.body_name = "right_gripper_base"

@configclass    
class Dual_Nero_ReachEnvCfg_PLAY(Dual_Nero_ReachEnvCfg):
    def __post_init__(self):
        # post init of parent
        super().__post_init__()
        # make a smaller scene for play
        self.scene.num_envs = 50
        self.scene.env_spacing = 2.5
        # disable randomization for play
        self.observations.policy.enable_corruption = False

4.2 Reach Task Definition

dual_nero_reach_env_cfg.py contains the full RL environment definition.

This includes:

1.Scene Configuration

• Ground plane

• Lighting

• Robot asset

2.Command Generation

3.Observation Space

4.Reward Design

5.Curriculum Learning

6.Episode Settings

import math
from dataclasses import MISSING

import isaaclab.sim as sim_utils
from isaaclab.assets import ArticulationCfg, AssetBaseCfg
from isaaclab.envs import ManagerBasedRLEnvCfg
from isaaclab.managers import ActionTermCfg as ActionTerm
from isaaclab.managers import CurriculumTermCfg as CurrTerm
from isaaclab.managers import EventTermCfg as EventTerm
from isaaclab.managers import ObservationGroupCfg as ObsGroup
from isaaclab.managers import ObservationTermCfg as ObsTerm
from isaaclab.managers import RewardTermCfg as RewTerm
from isaaclab.managers import SceneEntityCfg
from isaaclab.managers import TerminationTermCfg as DoneTerm
from isaaclab.scene import InteractiveSceneCfg
from isaaclab.utils import configclass
from isaaclab.utils.noise import AdditiveUniformNoiseCfg as Unoise

import isaaclab_tasks.manager_based.manipulation.reach.mdp as mdp
##
# Scene definition
##
@configclass
class Dual_NeroReachSceneCfg(InteractiveSceneCfg):
    """Configuration for the scene with a robotic arm."""

    # world
    ground = AssetBaseCfg(
        prim_path="/World/ground",
        spawn=sim_utils.GroundPlaneCfg(),
        init_state=AssetBaseCfg.InitialStateCfg(pos=(0.0, 0.0, 0)),
    )

    # robots
    robot: ArticulationCfg = MISSING

    # lights
    light = AssetBaseCfg(
        prim_path="/World/light",
        spawn=sim_utils.DomeLightCfg(color=(0.75, 0.75, 0.75), intensity=2500.0),
    )
##
# MDP settings
##
@configclass
class CommandsCfg:
    """Command terms for the MDP."""

    left_ee_pose = mdp.UniformPoseCommandCfg(
        asset_name="robot",
        body_name=MISSING,
        resampling_time_range=(4.0, 4.0),
        debug_vis=True,
        ranges=mdp.UniformPoseCommandCfg.Ranges(
            pos_x=(0.5, 0.5),
            pos_y=(0.15, 0.25),
            pos_z=(0.3, 0.5),
            roll=(-math.pi / 6, math.pi / 6),
            pitch=(3 * math.pi / 2, 3 * math.pi / 2),
            yaw=(8 * math.pi / 9, 10 * math.pi / 9),
        ),
    )

    right_ee_pose = mdp.UniformPoseCommandCfg(
        asset_name="robot",
        body_name=MISSING,
        resampling_time_range=(4.0, 4.0),
        debug_vis=True,
        ranges=mdp.UniformPoseCommandCfg.Ranges(
            pos_x=(0.5, 0.5),
            pos_y=(-0.25, -0.15),
            pos_z=(0.3, 0.5),
            roll=(-math.pi / 6, math.pi / 6),
            pitch=(3 * math.pi / 2, 3 * math.pi / 2),
            yaw=(8 * math.pi / 9, 10 * math.pi / 9),
        ),
    )

@configclass
class ActionsCfg:
    """Action specifications for the MDP."""
    left_arm_action: ActionTerm = MISSING
    right_arm_action: ActionTerm = MISSING
@configclass
class ObservationsCfg:
    """Observation specifications for the MDP."""

    @configclass
    class PolicyCfg(ObsGroup):
        """Observations for policy group."""

        # observation terms (order preserved)
        left_joint_pos = ObsTerm(
            func=mdp.joint_pos_rel,
            params={
                "asset_cfg": SceneEntityCfg(
                    "robot",
                    joint_names=[
                        "left_joint.*",
                    ],
                )
            },
            noise=Unoise(n_min=-0.01, n_max=0.01),
        )

        right_joint_pos = ObsTerm(
            func=mdp.joint_pos_rel,
            params={
                "asset_cfg": SceneEntityCfg(
                    "robot",
                    joint_names=[
                        "right_joint.*",
                    ],
                )
            },
            noise=Unoise(n_min=-0.01, n_max=0.01),
        )

        left_joint_vel = ObsTerm(
            func=mdp.joint_vel_rel,
            params={
                "asset_cfg": SceneEntityCfg(
                    "robot",
                    joint_names=[
                        "left_joint.*",
                    ],
                )
            },
            noise=Unoise(n_min=-0.01, n_max=0.01),
        )
        right_joint_vel = ObsTerm(
            func=mdp.joint_vel_rel,
            params={
                "asset_cfg": SceneEntityCfg(
                    "robot",
                    joint_names=[
                        "right_joint.*",
                    ],
                )
            },
            noise=Unoise(n_min=-0.01, n_max=0.01),
        )
        left_pose_command = ObsTerm(func=mdp.generated_commands, params={"command_name": "left_ee_pose"})
        right_pose_command = ObsTerm(func=mdp.generated_commands, params={"command_name": "right_ee_pose"})
        left_actions = ObsTerm(func=mdp.last_action, params={"action_name": "left_arm_action"})
        right_actions = ObsTerm(func=mdp.last_action, params={"action_name": "right_arm_action"})

        def __post_init__(self):
            self.enable_corruption = True
            self.concatenate_terms = True

    # observation groups
    policy: PolicyCfg = PolicyCfg()

@configclass
class EventCfg:
    """Configuration for events."""

    reset_robot_joints = EventTerm(
        func=mdp.reset_joints_by_scale,
        mode="reset",
        params={
            "position_range": (0.5, 1.5),
            "velocity_range": (0.0, 0.0),
        },
    )

@configclass
class RewardsCfg:
    """Reward terms for the MDP."""
    left_end_effector_position_tracking = RewTerm(
        func=mdp.position_command_error,
        weight=-0.2,
        params={
            "asset_cfg": SceneEntityCfg("robot", body_names=MISSING),
            "command_name": "left_ee_pose",
        },
    )
    right_end_effector_position_tracking = RewTerm(
        func=mdp.position_command_error,
        weight=-0.25,
        params={
            "asset_cfg": SceneEntityCfg("robot", body_names=MISSING),
            "command_name": "right_ee_pose",
        },
    )
    left_end_effector_position_tracking_fine_grained = RewTerm(
        func=mdp.position_command_error_tanh,
        weight=0.1,
        params={
            "asset_cfg": SceneEntityCfg("robot", body_names=MISSING),
            "std": 0.1,
            "command_name": "left_ee_pose",
        },
    )
    right_end_effector_position_tracking_fine_grained = RewTerm(
        func=mdp.position_command_error_tanh,
        weight=0.2,
        params={
            "asset_cfg": SceneEntityCfg("robot", body_names=MISSING),
            "std": 0.1,
            "command_name": "right_ee_pose",
        },
    )
    left_end_effector_orientation_tracking = RewTerm(
        func=mdp.orientation_command_error,
        weight=-0.1,
        params={
            "asset_cfg": SceneEntityCfg("robot", body_names=MISSING),
            "command_name": "left_ee_pose",
        },
    )

    right_end_effector_orientation_tracking = RewTerm(
        func=mdp.orientation_command_error,
        weight=-0.1,
        params={
            "asset_cfg": SceneEntityCfg("robot", body_names=MISSING),
            "command_name": "right_ee_pose",
        },
    )
    # action penalty
    action_rate = RewTerm(func=mdp.action_rate_l2, weight=-0.0001)
    left_joint_vel = RewTerm(
        func=mdp.joint_vel_l2,
        weight=-0.0001,
        params={
            "asset_cfg": SceneEntityCfg(
                "robot",
                joint_names=[
                    "left_joint.*",
                ],
            )
        },
    )
    right_joint_vel = RewTerm(
        func=mdp.joint_vel_l2,
        weight=-0.0001,
        params={
            "asset_cfg": SceneEntityCfg(
                "robot",
                joint_names=[
                    "right_joint.*",
                ],
            )
        },
    )
@configclass
class TerminationsCfg:
    """Termination terms for the MDP."""
    time_out = DoneTerm(func=mdp.time_out, time_out=True)
@configclass
class CurriculumCfg:
    """Curriculum terms for the MDP."""
    action_rate = CurrTerm(
        func=mdp.modify_reward_weight,
        params={"term_name": "action_rate", "weight": -0.005, "num_steps": 4500},
    )

    left_joint_vel = CurrTerm(
        func=mdp.modify_reward_weight,
        params={"term_name": "left_joint_vel", "weight": -0.001, "num_steps": 4500},
    )

    right_joint_vel = CurrTerm(
        func=mdp.modify_reward_weight,
        params={"term_name": "right_joint_vel", "weight": -0.001, "num_steps": 4500},
    )
##
# Environment configuration
##
@configclass
class Dual_NeroReachEnvCfg(ManagerBasedRLEnvCfg):
    """Configuration for the reach end-effector pose tracking environment."""
    # Scene settings
    scene: Dual_NeroReachSceneCfg = Dual_NeroReachSceneCfg(num_envs=4096, env_spacing=2.5)
    # Basic settings
    observations: ObservationsCfg = ObservationsCfg()
    actions: ActionsCfg = ActionsCfg()
    commands: CommandsCfg = CommandsCfg()
    # MDP settings
    rewards: RewardsCfg = RewardsCfg()
    terminations: TerminationsCfg = TerminationsCfg()
    events: EventCfg = EventCfg()
    curriculum: CurriculumCfg = CurriculumCfg()

    def __post_init__(self):
        """Post initialization."""
        # general settings
        self.decimation = 2
        self.sim.render_interval = self.decimation
        self.episode_length_s = 24.0
        self.viewer.eye = (3.5, 3.5, 3.5)
        # simulation settings
        self.sim.dt = 1.0 / 60.0



\`\`\`



**### 4.3 Registering the Environment**



Register the task inside:\`src/isaac_so_arm101/tasks/reach/\__init_\_.py\`



\`\`\`PYTHON

gym.register(

    id="Isaac-Dual-Nero-Reach-v0",

    entry_point="isaaclab.envs:ManagerBasedRLEnv",

    kwargs={

        "env_cfg_entry_point":f"{\__name_\_}.dual_nero_joint_pos_env_cfg:Dual_Nero_ReachEnvCfg",

        "rsl_rl_cfg_entry_point": f"{agents.\__name_\_}.rsl_rl_ppo_cfg:ReachPPORunnerCfg",

        "rl_games_cfg_entry_point": f"{agents.\__name_\_}:rl_games_ppo_cfg.yaml",



    },

    disable_env_checker=True,

)

5. Training the Reach Policy

Step 1.Activate the Isaac Lab Environment

conda activate env_isaaclab

Step 2.Navigate to the project directory:

cd isaac_so_arm101

Step 3.Train the whole project

Option 1:RSL-RL

• Train:

uv run train \

    --task Isaac-Dual-Nero-Reach-v0 \

    --headless

• Evaluate:

uv run play \

    --task Isaac-Dual-Nero-Reach-v0

• Training result:

dual_nero_rsl_rl.gif

Option 2: RL-Games

• Train:

python3 scripts/rl_games/train.py \
    --task Isaac-Dual-Nero-Reach-v0 \
    --headless

• Evaluate:

python3 scripts/rl_games/play.py \
    --task Isaac-Dual-Nero-Reach-v0

• Training result:

dual_nero_rl_games.gif

6. Results and Observations

Both frameworks successfully learn the dual-arm reaching task.

However, in our experiments:

• RL-Games converges faster

• Motion trajectories appear smoother

• Final reaching accuracy is generally higher

For relatively complex robot morphologies such as dual-arm manipulators, RL-Games currently provides more stable performance and is recommended as the default training backend.

FAQ

Q1: Why is my Dual-Nero robot collapsing or shaking violently after loading the URDF?

This is usually caused by incorrect actuator parameters or unrealistic inertial properties.

Common causes include:

1. Joint stiffness set too high

2. Damping values too low

3. Incorrect mass distribution in the URDF

4. Self-collision configuration issues

5. Unstable simulation timestep

Before starting RL training, verify that the robot can remain stable under gravity using only PD control.

Quick check: If the robot cannot stand still without RL, the issue is likely in the robot model rather than the training algorithm.

Q2: Why does the reward improve, but the robot never reaches the target accurately?

A rising reward does not always indicate successful task completion.

Typical reasons include:

• Reward weights are unbalanced

• Orientation rewards dominate position rewards

• Action penalties are too strong

• Command sampling range is too large

• End-effector link is incorrectly configured

In most reach tasks, incorrect reward shaping is the primary reason for poor final accuracy.

Q3: How do I verify that the end-effector link is configured correctly?

One of the most common mistakes in Isaac Lab reach tasks is assigning the wrong end-effector body.

For Dual-Nero, the target link should be:

left_gripper_base

right_gripper_base

Symptoms of an incorrect configuration include:

• Reward remains low

• Robot moves randomly

• Training appears to converge but fails visually

• End-effector does not move toward the target marker

Always verify the body name in Isaac Sim before launching large-scale training.

Q4: Why does RL-Games perform better than RSL-RL for this task?

Both frameworks are PPO-based, but their implementations differ.

For large-scale manipulation environments:

RL-Games generally scales better with thousands of parallel environments

PPO updates are often more stable

Training throughput is higher on modern GPUs

For Dual-Nero reach experiments, RL-Games typically achieves smoother trajectories and faster convergence.

However, results may vary depending on reward design and task complexity.

Q5: My policy works in simulation but fails on the real robot. Why?

This is the most common Sim-to-Real issue.

Possible causes include:

• Joint friction mismatch

• Encoder noise

• Latency differences

• Payload variations

• Inaccurate motor models

• Unmodeled cable effects

To improve transfer performance:

• Apply domain randomization

• Add observation noise

• Randomize dynamics parameters

• Validate trajectories at low speed first

Successful simulation training is only the first step toward real-world deployment.

Have Question?

If you encounter any issues with environment installation, parameter configuration, or RL training, feel free to leave your questions for further discussion.

1 post - 1 participant

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Hello, would you be interested in building a ROS2 vacuum cleaner robot?

If yes

1. Build/develop vs convert existing?
2. 3D print vs off-the-shelf?
3. Convert existing - root or swap board?

I’d really appreciate your input.

As an example of what I’m doing

• I have connected my vacuum to ROS including /scan, /imu, /cmd_vel, /odom, brushes (main, side), vacuum fan, IR sensors. Open source here GitHub - makerspet/proscenic-m6pro: ROS2 robot description for Proscenic M6 Pro · GitHub
• I have had a consumer vacuum cleaner robot torn down, converted to 3D design to experiment with 3D printing it. Open source here GitHub - remakeai/vacuum_cleaner_teardown: Teardown of a home robot vacuum cleaner equipped with LiDAR · GitHub

1 post - 1 participant

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Hi Intrinsic / AIC team,

I’m working on AIC Phase 1 in Flowstate and trying to run my participant model as a custom Service instance named exactly aic_model.

The baseline AIC Phase 1 Submission process expects:

• lifecycle service: /aic_model/change_state
• action server: /insert_cable

I have a local Docker image:

my-solution:phase1_basic_control_ladder

The image works in local Docker Compose when launched with the AIC router environment variables. Its entrypoint requires:

AIC_ROUTER_ADDR

and may require AIC_MODEL_PASSWD if ACL is enabled.

From inspecting the SDK/Flowstate tooling, it looks like the possible path is:

inctl asset install <bundle.tar> --org ... --cluster ...
inctl service add <service_asset_id_version> --cluster ... --name aic_model

I can package the Docker image as a Service asset bundle, but I don’t want to guess the router environment contract.

Questions:

1. For a custom Flowstate Service instance named aic_model, does Flowstate automatically inject AIC_ROUTER_ADDR and AIC_MODEL_PASSWD?
2. If not, what should AIC_ROUTER_ADDR be set to in simulation inside the Flowstate VM?
3. What is the approved way to provide AIC_MODEL_PASSWD without exposing secrets?
4. Is inctl asset install + inctl service add --name aic_model the intended local Flowstate testing workflow for AIC Phase 1, or is there another approved way to make the participant model available to the solution?

Thanks!

1 post - 1 participant

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Introducing CycloneDDS Insight - Graphical DDS Inspection and Debugging for ROS 2.

CycloneDDS Insight is a graphical DDS inspection and debugging tool for ROS 2 and Eclipse Cyclone DDS.

The tool provides visibility into DDS participants, topics, publishers and subscribers, helping users understand system topology, diagnose discovery issues and analyze communication behavior in distributed ROS 2 systems.

Features include:
* Live inspection of DDS entities
* Discovery and communication debugging
* Visualization of communication architectures
* DDS traffic and statistics monitoring
* Support for complex multi-host ROS 2 deployments

CycloneDDS Insight is completely free and open source, making advanced DDS inspection and debugging capabilities accessible to everyone in the ROS 2 community.

Repository:
https://github.com/eclipse-cyclonedds/cyclonedds-insight

Feedback and contributions are welcome.

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A few months ago I had an odd thought (as an occasional modelmaker), has anyone ever made a model of a ROS robot? An AGV, a PR2 to sit on your desk? A Moose? It should be fairly straightforward even, because practically all robot description packages ship a mesh of the robot for rviz which can be fixed up a little and 3D printed to get an exact replica.

I’ve searched quite a bit but couldn’t find anything like that online. So I guess it fell to me to make the first entry.

I got the idea when looking at the ST3045M, the microservo variant of the really practical ST3215 that everyone’s using in SO-ARMs. Something so tiny with full positional and velocity control, low speed torque, odom feedback, and one wire control is like the holy grail for modelmaking.

My first plan was Segway’s Nova Carter, since it’s a fairly aesthetic design, but some miscalculations later I realized it’s way too narrow for it to work with these servos. Clearpath’s Husky or Jackal would work, but then I found Husarion’s Lynx which both looks cooler and the wheel shafts line up almost perfectly when scaled down.

So a few months later, here’s the end result: A 1/5 scale model with most of the capabilities of the real thing, except maybe runtime and a slightly lower scale top speed:

The shell is 3D printed PLA, spray painted, plus some minor weathering with chrome paint, the tires are just off the shelf 1/24 scale crawler wheels with printed hubs. I’ve used double ended LED filaments to make the RGB strips, even the WS2812C is too large at this scale.

I had to modify the servos a bit, sawing off the mounting plates on one side so the shafts would be close enough to the end of the chassis without them poking out. They occupy the entire bottom third:

I was planning to use a Pi Zero 2, but the performance meant it would never be able to run anything useful. The only realistic other option was a CM4 + a drone carrier board to leave me enough space for the other stuff. Expensive but totally worth it imo, since it also has very compact pixhawk connectors and an external antenna plug. I had to take some creative liberties in the rear, extending it out a bit and flattening it so the parts would fit.

(no the tiny estop doesn’t work, sorry )

As for how I made it run nav2 without a lidar is… well that it does actually have a built in lidar. There’s a Vl53L7CX in the front that behaves a lot like a really garbage stereo camera with only 64 pixels, from which I can extract a horizontal line or two, make some hilarious assumptions and boom a laserscan. Needless to say slam_toolbox recoils in horror unless I disable scan matching, but the wheel odom + BNO085 is actually totally enough to map that way for short periods.

And here are the internals, I’m not really patient enough to make my own PCBs, so it’s just a bunch of dev boards with gratuitous components removed, wrapped in kapton tape and shoved in there.

My enemy throughout the build was heat. I’ve never attempted anything this compact before and with such high power components the second chassis just melted around the CM4. I thought passive cooling will be enough, but even with a heatsink the size of the entire rear end it didn’t really help. So it needs the fan, and extra vents in the wheel wells and the top to help keep the battery cool too. The wheels are ultra soft, which is nice for grip (it can climb up a 30 deg slope out of smooth metal) but they also almost tear off when turning in place on rough surfaces.

The pogo pins in the front are for charging and I have an apriltag dock planned, but I still need to find a usb webcam that looks scale and design a gantry that mounts on top…

I’ve documented most of the setup, since it’s convoluted enough that I’ll forget half of it in two months otherwise, but hopefully it comes in useful for anyone else, there’s some videos there too:

I wouldn’t really recommend anyone to try and recreate it strictly based on that since it’s hardly complete, but I really hope it comes in handy as an inspiration or learning reference. I would just love to see if anyone else has already made something but just never posted it, or if hopefully this gives someone the idea to make something similar. I think a Nova Carter is genuinely doable with geared micro steppers after seeing this thing the other day.

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Full disclosure up front: I work on ZeroDDS, so this is our project, not a neutral review. Sharing it here because it’s specifically aimed at problems this community has been reporting for years, and we’d genuinely like the feedback.

What it is: an alternative RMW for ROS 2, with the whole DDS stack underneath written from scratch in Rust (memory-safe, Apache-2.0, no per-seat license). It speaks native RTPS 2.5 and interoperates with your existing setup: ROS 2 over `rmw_zerodds` talks to ROS 2 over `rmw_cyclonedds` bidirectionally (20/20 in our pub/sub + service tests). It’s a drop-in `RMW_IMPLEMENTATION`, not a fork of your graph.

We didn’t guess at the pain, we catalogued it. Before writing “ROS 2 support” anywhere, we collected 349 real-world ROS↔DDS pain reports from this forum, GitHub and elsewhere, and engineered against the recurring ones:

• Silent QoS / type mismatches — the classic where two endpoints just never match and nothing is logged. Fixed the keyed/no-key entity-id case, and shipped `zerodds-ros2-shim doctor`, a discovery-independent check that flags the most common WiFi misconfig (multicast-free with no unicast peers) as a hard error instead of a silent no-match.

• WiFi discovery loss — a single SPDP beacon dropped during 802.11 power-save leaves you at `participants=0`. We send an initial-announcement burst (10×200 ms until matched), like FastDDS’ `initial_announcements`. Verified on a real WiFi rig, not just loopback.

• Large fleets / WAN — a `multi_robot()` profile: unicast-only discovery, no multicast storm.

• DDS-Security / SROS2. ZeroDDS consumes SROS2 enclave files (identity/permissions CA, cert, key, governance, permissions) and fails hard on a broken config (no silent downgrade). Caveat for ROS-users: today you point it at the enclave via a ZERODDS_SECURITY_DIR env var, not the standard ROS_SECURITY_KEYSTORE / ROS_SECURITY_ENABLE variables yet. Wiring those up so ros2 security works unmodified is still open.

• Introspection — `ros2 topic info -v` resolves endpoint GUIDs to node names.

Works with rclpy and rclcpp.

New in rc.3: zero-copy shared memory now works on Windows too (via `CreateFileMapping` + `LockFileEx`), tested on a real Windows runner.

Next (rc.4): a continuous multi-distro live `ros2` smoke as a CI gate across Humble, Iron and Jazzy, so interop is proven on every commit rather than by hand. The `rmw_zerodds` surface itself is code-complete (pub/sub, services, wait-sets, loaned messages, REP-2009 type hash + endpoint info; nothing left `UNSUPPORTED`).

Honest about maturity: it’s a release candidate, not years-hardened. On performance we’re on par with the established stacks across real workloads, not uniformly ahead, and we don’t claim to beat RT-tuned commercial configs. An OMG Vendor-ID is filed but not yet assigned. We are not safety-certified.

Try it:

• build the rmw layer and run `RMW_IMPLEMENTATION=rmw_zerodds_cpp ros2 …`

• repo + docs: GitHub - zero-objects/zero-dds: OSS DDS implementation in Rust · GitHub · https://zerodds.de

If you hit a mismatch with your Cyclone/Fast-DDS nodes, or a QoS combination that doesn’t behave, that’s exactly the feedback we want. Tell us where it breaks.

(For the DDS/non-ROS folks who wander in: the same codebase also covers XTypes, DDS-Security, RPC, bridges, seven language bindings, and a full CORBA 3.3 ORB. Happy to go into any of it, but I’ll keep this post ROS-focused.)

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ROS2 Quick Runner

This is a VSCode extension I recently wrote, and I’ve been using it lately

A VS Code extension for quickly running ROS2 launch files, Python nodes, and C++ nodes.

GitHub - Knighthood2001/vscode-ros2-quick-runner: Quickly run ROS 2 launch, Python, and C++ files in VSCode · GitHub

Features

1. Launch ROS2 Files

Right-click any .launch.py file and select “ros2 launch” to:

• Automatically find the ROS2 workspace
• Source the workspace’s install/setup.bash
• Execute ros2 launch <package_name> <launch_file>

2. Run ROS2 Nodes

Right-click any .py or .cpp file and select “ros2 run” to:

• Automatically find the ROS2 workspace and package name
• Source the workspace’s install/setup.bash
• Execute ros2 run <package_name> <node_name>

3. Get Workspace Name

Right-click any file and select “ros2 source” to:

• Display the workspace name
• Source the workspace in a new terminal

4. Build ROS2 Workspace

Right-click any folder in your ROS2 workspace and select “colcon build” to:

• Automatically find the ROS2 workspace root
• Open a terminal at the workspace root
• Execute colcon build

Smart path detection:

• Right-click xxx_ws/ → build in xxx_ws/
• Right-click xxx_ws/src/ → build in xxx_ws/
• Right-click any sub-folder (e.g. xxx_ws/src/pkg_a) → build in xxx_ws/

How It Works

The extension automatically:

1. Finds the ROS2 workspace by searching for directories whose src/ subdirectory contains at least one package with package.xml
2. Extracts the package name by parsing the package.xml file in the package directory
3. Executes commands in a new VS Code terminal

Usage

1. Search for ros2-quick-runner in VS Code extensions and install it
2. Open your ROS2 project in VS Code
3. Right-click on a file in the explorer:
   • .launch.py files → “ros2 launch”
   • .py or .cpp files → “ros2 run”
   • Any file → “ros2 source”
   • Any folder → “colcon build”

Commands

Requirements

• VS Code 1.80.0 or higher
• ROS2 installed (e.g., ROS 2 Humble)
• A compiled ROS2 workspace with install/ directory

Release Notes

For detailed changelog, please see: vscode-ros2-quick-runner/CHANGELOG.md at main · Knighthood2001/vscode-ros2-quick-runner · GitHub

0.0.3

• Initial release
• Support for ROS2 launch files, Python nodes, and C++ nodes
• Automatic workspace detection
• Automatic package name extraction

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Hi everyone,

“ROS is used to build robots, but isn’t it time for ROS to have its own robot?�

I’m excited to share a tool I’ve been working on to make ROS 2 development a bit smoother: Ros2 Robot.

As developers, we spend a lot of time typing repetitive terminal commands just to manage packages, source workspaces, and inspect topics. I wanted to build a tool that handles the boilerplate so we can focus on actual robotics innovation. It also serves as a great stepping stone for newcomers who find the ROS 2 CLI overwhelming.

What is it?
Ros2 Robot is a PyQt/PySide6 based GUI that acts like “GitHub Desktop� for your ROS 2 projects.

Key Features in V1.0.0:

• Create packages, rebuild, and source them all with one click.
• Run and manage nodes all from one place.
• Inspect topics in real-time.
• Manage ROS bags effortlessly.
• Build launch files by adding blocks.
• Visualize your URDF files and control your joints.
• Open your favorite ROS Plugins directly from the interface.
• Educational: understand what each feature does in the background CLI.
• Supports Native Linux (Tested On Ubuntu 22.04/24.04) and Windows with WSL 2!

Installed with ��� ����, and launched with ��� �������.

GitHub Repository: GitHub - saheraalreqeb/Ros2_Robot: Ros2 Robot is a simple GUI designed to help you manage your ROS 2 projects a. Think of it as GitHub Desktop, but for ROS 2. It eliminates those repetitive, soul-crushing terminal commands so you can actually focus on coding and development. · GitHub
(I’ll be posting a full video tutorial later today showing it in action!)

I’m releasing this as V1.0.0 because the core features are stable, but this is just the beginning. I would love for the community to test it out. If you encounter bugs, have ideas for new features, or want to contribute code, please head over to the GitHub repo and open an issue or a PR.

Let me know what you think!

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Seeking Feedback from Robotics Software Engineers / ROS Developers

Hello everyone,

I hope you are doing well.

I am a BE Computer Science student with a strong interest in robotics software. I am currently researching a potential software product and, before investing significant time into building it, I would like to validate whether the problem I am trying to solve is a genuine challenge faced by robotics engineers.

From my research, I have observed that robotics engineers are often blocked because another part of the robot is not yet available or is temporarily broken. For example:

• A navigation engineer cannot continue because localization is not ready.
• A manipulation engineer cannot continue because MoveIt is unavailable or malfunctioning.
• A docking engineer cannot test their feature because the navigation stack is incomplete.

To continue development, engineers often write temporary Python scripts, use ROS CLI commands, or create custom test nodes just to simulate missing robot components.

The idea I am exploring is a ROS-native platform that allows engineers to discover, call, mock, save, and reuse ROS 2 Actions and Services through a visual interface, helping them continue development without waiting for missing dependencies.

Before building anything, I would sincerely appreciate your honest opinion.

1. Have you experienced dependency-blocking situations like these in your projects?
2. How do you currently work around these problems?
3. If this problem exists, how painful is it in day-to-day development?
4. Do you think a tool like this would provide meaningful value, or am I solving the wrong problem?
5. Is there any existing tool that already solves this problem well?
6. Is there anything important that I might be overlooking?

I genuinely welcome honest criticism, even if your opinion is that this problem is not worth solving. Constructive feedback would help me avoid spending months building something that isn’t valuable to the robotics community.

If anyone is willing to discuss this in more detail, I would be sincerely grateful for even 10–15 minutes of your time through a direct message, phone call, or Google Meet at your convenience.

Thank you very much for taking the time to read this post. I truly appreciate any feedback, suggestions, or guidance you are willing to share.
is this good and worth posting

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Been thinking about this for a while.

The chi-squared gate in most localization stacks assumes Gaussian noise. When when we look outdoors… it rarely is. Like doing multipath near buildings, or under tree canopy, and even around field equipment.

I came across this conformal prediction (Angelopoulos & Bates 2022). The idea is: instead of assuming a distribution, you basically test each new measurement against your own empirical data. It states coverage guarantees hold regardless of noise shape.

Has anyone tried something like this in a nav stack? And honestly… is GPS covariance mismatch painful enough in real deployments that it’s worth a proper fix, or does tuning R get you 90% of the way there?

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