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As ROS2 fleets move into commercial deployments serving external clients, one infrastructure gap is shared economic verification between the fleet operator and their customer. The operator’s internal logs don’t give the client independent verification of what work was completed, leading to manual reconciliation and disputes as fleets scale.

Built a settlement layer that monitors ROS2 lifecycle events and generates verified timestamped records per robot per completed task. Both operator and client can verify independently. Each robot builds a portable work history over time useful for service billing, equipment valuation, and proving utilization to potential customers.

Already compatible with standard ROS2 lifecycle management. Integration details here:https://github.com/FoundryNet/foundry_net_MINT/blob/main/FoundryNet%20API%20Client/foundry-client.py

Interested in feedback from anyone deploying ROS2 fleets commercially and dealing with the billing side of multi-client operations.

Cheers!

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Hi everyone!

Like many of us, I appreciate the power and flexibility of ROS 2, but I’ve always found the amount of manual boilerplate to be a bottleneck for rapid development. Keeping track of all the configuration details making sure CMakeLists.txt and package.xml are perfectly synced, or manually wiring launch files and topic connections takes a significant amount of time. I wanted to find a way to automate this infrastructure setup so I could focus purely on writing the actual robotics logic.

To solve this, I started building ROS 2 Blueprint Studio a visual node-based editor (inspired by Unreal Engine Blueprints) designed to take the routine off your shoulders.

Under the Hood (Architecture) I tried to avoid any “black magic” and stick entirely to standard ROS 2 practices:

1. Code Generation & Build System The studio doesn’t compile the code itself; it acts as a smart templating engine. Creating a standard node generates a base C++ template. If you duplicate a node (from the palette or canvas), it creates an independent file with a new name and copied code. Modifying the copy doesn’t break the parent. For the actual build, it relies on standard colcon build under the hood.

2. File Watcher & Dependency Tree To build the dependency tree, I wrote a custom FileWatcher. Before building, it scans the files to check for includes and node communication. For performance, it only parses files that have been modified. (I realize this might theoretically cause “phantom connections” on massive graphs, so I plan to add a forced full-rebuild mode in the future).

3. Topic Routing (Two Approaches) Node linking currently works in two modes:

• Hardcoded (Bottom-Up): If publisher and subscriber topic names are explicitly hardcoded in your C++ or Python files, the UI detects this and automatically draws a visual “locked” wire between them.

• Visual (Top-Down): You can define the topic name only on the publisher, drag a visual wire to a subscriber, and the FileWatcher will find a special placeholder in the subscriber’s code and automatically replace it with the publisher’s topic name. (Full disclosure: the visual routing is still a bit unstable and not recommended for huge projects yet, but I’m refining it).

4. Runtime Environment (Docker) I chose Docker (osrf/ros:humble-desktop) as the execution environment. Why?

• Setting up ROS 2 natively on Windows is a special kind of pain.

• It provides painless deployment and saves you from dependency hell when migrating to future ROS versions.

• You can send your project folder to someone who doesn’t even have ROS installed, and their system will build and run your entire architecture in just a few clicks.

The Ask: Roast My Architecture The project is currently in early alpha. Honestly, my biggest doubts right now are around the core architecture and the automated build system (package and launch file generation).

I would be incredibly grateful if experienced ROS architects could take a look at the repo, point out my blind spots, and give me some harsh architectural critique. I’d much rather rebuild the foundation now than drag architectural flaws into a full release.

Source code here: GitHub - NeiroEvgen/ros2-blueprint-studio · GitHub

Any feedback is highly appreciated!

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mcp-ros2-logs is an open-source MCP server that merges ROS2 log files from multiple nodes into a unified timeline and exposes query tools for AI agents like Claude, GitHub Copilot, and Cursor.

The problem: ROS2 writes each node’s logs to a separate file. Debugging a cascading failure across sensor_driver -> collision_checker -> motion_planner means manually correlating timestamps across 3+ files.

What this does: Install it with pipx install mcp-ros2-logs, register it with your AI assistant, and ask natural language questions like:

• “show me all errors with 5 messages of context around each”
• “compare good_run vs bad_run — what changed?”
• “detect anomalies in this run”
• “correlate errors with bag topics — what was happening on /scan when the planner crashed?”

Features:

• 12 MCP tools: query logs, node summaries, timelines, run comparison, anomaly detection, bag file parsing, log-to-bag topic correlation, live tailing
• Parses ROS2 bag files (.db3/.mcap) without ROS2 installed — extracts topic metadata for correlation with log errors
• Statistical anomaly detection: rate spikes, new error patterns, severity escalations, silence gaps, error bursts
• Supports custom RCUTILS_CONSOLE_OUTPUT_FORMAT
• Works with Claude Code, VS Code Copilot, Cursor, and any MCP-compatible client
• No ROS2 installation required — it just reads files from disk

Example workflow: Point the agent at a run where a lidar USB connection dropped. It loads the logs, correlates the errors with bag topic data, and reconstructs the full causal chain: USB timeout → /scan messages stopped → collision_checker failed → motion_planner aborted. The whole analysis takes about 10 seconds.

GitHub: GitHub - spanchal001/mcp-ros2-logs: Give AI agents the ability to debug ROS2 logs across nodes — MCP server, no ROS2 install required · GitHub
PyPI: pipx install mcp-ros2-logs

Would love feedback from anyone doing multi-node debugging or working with bag files.

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Title: Rewire — stream ROS 2 topics to Rerun with zero ROS 2 build dependencies

Hi all,

I’ve been working on Rewire, a standalone bridge that streams live ROS 2 topics to
Rerun for real-time visualization. I wanted to share it here and get feedback from the
community.

The problem it solves

Setting up visualization tooling in ROS 2 often means pulling in dependencies,
building packages, and dealing with middleware configuration. I wanted something that just works — point it at a DDS/Zenoh network and start visualizing.

How it works

Rewire is a single Rust binary that speaks DDS and Zenoh wire protocols directly. It’s not a ROS 2 node —
it doesn’t join the ROS graph or require any ROS 2 installation. It acts as a passive observer.

curl -fsSL https://rewire.run/install.sh | sh
rewire record -a    # subscribe to all topics

What’s supported

• 53 type mappings across sensor_msgs, geometry_msgs, nav_msgs, tf2_msgs, vision_msgs, std_msgs, and rcl_interfaces — including Image, PointCloud2, LaserScan, TF, Odometry, Detection2D/3DArray, and more.
• Custom message mappings — map any ROS 2 message type to Rerun archetypes via a JSON5 config file, no recompilation.
• URDF visualization — loads from /robot_description, resolves meshes via AMENT_PREFIX_PATH.
• Full TF tree — static + dynamic transforms with coordinate frame visualization
• Per-topic diagnostics — Hz, bandwidth, drops, and latency rendered as Rerun Scalars.
• Topic filtering — glob-based include/exclude patterns.

Platforms

Linux (x86_64, aarch64) and macOS (Intel + Apple Silicon).

Install options

• Install script: curl -fsSL https://rewire.run/install.sh | sh
• prefix.dev: pixi global install -c rewire rewire
• APT repository for Debian/Ubuntu

I’d love to hear your thoughts — especially around which message types or workflows you’d want supported next. If you run into issues, feedback is very welcome.

Website: https://rewire.run

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Hello ROS community

When working with Lidar data users are usually referred to using PointCloud2 objects that represent the lidar data as a list of 3d points with additional attributes. While this nicely mirrors the PCL representation and fits the majority of applications working with 3D point cloud data this isn’t how modern lidar sensors represent data.

Problem Statement

This has several drawbacks that are highlighted in the following list (not a comprehensive list):

• With the rapid increase in Lidar resolution, PointCloud2 can be hefty to transport..To this date many DDS implementations struggle to catch up with the actual sensor frame rate when transporting a high resolution PointCloud2 on low to medium compute nodes.

• An option to reduce the bandwidth requirement would be to use dense pointclouds i.e. transport only valid points. However, by doing so we lose the structured nature of Lidar data of devices that natively generated the Lidar data in a structured 2D grid.

  • Many image processing operations do benefit from the adjacency information allowing for quick lookup of neighboring pixels. For example, Ground Plane Removal can be more efficient to implement directly on 2D range data than using a 3D representation.

  • One could also directly employ existing 2D neural networks like YOLO on Lidar data in their 2D representation.

• A potential critique to this suggestion might be that we don’t need a new message to do this as we already have sensor_msgs::Image that can fulfill this aspect for users who need it to be that way. And in fact, the ouster_ros driver -optionally- does publish the range data and other byproducts of the sensor as sensor_msgs::Image on separate topics. I am aware of many users who do indeed utilize these topics instead of the 3d pointcloud data.

  • While this works fine if you are only interested in processing each channel individually. This breaks down a bit if you need to access and use more than one channel in the same operation - which is often the case -.

    • A simple example of this, a user may want to filter certain returns (range data) based on reflectivity values and adjacency data simultaneously.

  • A common approach to this problem in ROS would be to use the `ApproximateTime` filter. Doing so, however, adds some latency and CPU overhead to synchronize data channels that were originally already synchronized.

  • A LidarScan message acts here as a multi-spectral image with all channels are memory aligned with 100% data correlation ensured by the sensor without software sync overhead.

The proposal

We are proposing the addition of a new ROS sensor message that mirror that native format of the majority of Lidar sensors (whether spinning or solid-state), in this proposal we would like to invite other lidar vendors to also contribute to make sure that this format encompasses the entire spectrum of Lidar sensors.

A quick draft of a LidarScan message could look like this:

std_msgs/Header header

# Dimensions of the scan (e.g., 128 channels x 2048 columns)
uint32 height
uint32 width

# --- Geometry Metadata ---
# Horizontal and Vertical FOV/Resolution info to allow projection to 3D 
# without needing a full PointCloud2 blob.
float32 vertical_fov_min
float32 vertical_fov_max
float32 horizontal_fov_min
float32 horizontal_fov_max

# --- Channel Data (The "Image" approach) ---
# Each channel (Range, Intensity, Reflectivity, etc.) is stored in this list.
# This mirrors the 'PointField' logic but at a 2d-grid level.
LidarChannel[] channels

# The actual raw buffer containing all interleaved or planar channel data.
# Using uint8[] allows for Zero-Copy compatibility.
uint8[] data

# --- Scaling and Metrics ---
# Different venders have different units
# Ouster (mm) vs. Velodyne (m) vs. Hesai (cm) problem.
# Range = (raw_value * multiplier) + offset
float64 range_multiplier
float64 range_offset

And the definition of LidarChannel:

string name        # "range", "intensity", "reflectivity", "ambient", "near_ir"
uint32 offset      # Offset from start of data row
uint8  datatype    # uint8, uint16, uint32, float32, etc.

While this works for sensors with uniform distributions of laser beams not all vendors have that formation including Ouster sensors making the section on Geometry Metadata insufficient:

float32 vertical_fov_min
float32 vertical_fov_max
float32 horizontal_fov_min
float32 horizontal_fov_max

Ouster spinning sensors vertical beams don’t have uniform distribution due to the calibration process. Which means we need to extend the previous definition to include the beam angels in the LidarScan message body:

# --- Non-Uniform Geometry Metadata ---
# These arrays allow the receiver to project Range -> 3D.
# vertical_angles[height]: The elevation angle for each ring (in radians).
float32[] vertical_angles

# other attributes might also be needed
# horizontal_angles[width]: [optional] The azimuth angle for each column (in radians).
# int32[] beam_time_offset: [optional] To handle "staggered" firing patterns within a single column.

This solves the problem and allows users to project the range data into 3D but adds a bit of overhead increasing the message size. These arrays basically essentially define the intrinsics of the Lidar sensor, however, transporting them with every LidarScan message reduces or eliminates most of the gains attained by transporting the raw range data vs using the projected xyz points. A better approach would be to break down the beam information and the lidar data into two separate messages in which the lidar sensor info is only transported once earlier during the connection phase. This is not a new pattern to ROS as it already has `sensor_msgs/CameraInfo` which describes the intrinsics of the camera link: sensor_msgs/CameraInfo Documentation .

By moving these intrinsic values fields into a separate message we can retain the same gains and keep the LidarScan message lean. The definition for a sensor_msgs::LidarInfo message would be something like:

std_msgs/Header header

float32[] vertical_angles
float32[] horizontal_angles
int32[] beam_time_offsets

# --- Scaling and Metrics ---
float64 range_multiplier
float64 range_offset

# Plus other static factory data (intrinsic/extrinsic)

And the revised LidarScan message becomes:

std_msgs/Header header
uint32 height
uint32 width
LidarChannel[] channels
uint8[] data

NOTES:

• This format is more suited for filtering and perception stacks

• It is important to note that this proposal does not suggest that vendors of Lidar sensors or users should stop using the PointCloud2. It mainly suggests the addition of a new message type that mirrors the native format of the majority of Lidar sensors, reducing overhead and providing better synchrony.

• The idea here is to come up with a standard sensor_msgs::LidarScan and sensor_msgs::LidarInfo messages .. and totally abstract out the process that converts this native Lidar sensor message format and produce the 3D pointcloud out of any sensor.

• Once we get initial feedback from the community the idea is that Ouster and others who are interested in this concept to build a PoC of the proposal and make sure we cover the all basic necessities for this to work before committing to the final interface.

• I am also aware of the other proposals around Native Buffers (rcl::Buffer) that are already in flight and we plan to support this from the get go as there are large intersection with the motivation behind Native Buffers and the use of LidarScan for perception type of tasks and other workloads

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ROSCon Global 2026 Call for Proposals Now Open!

The ROSCon call for proposals is now open! You can find full proposal details on the ROSCon 2026 website.

ROSCon Global 2026 will be held in Toronto, Canada, from September 22nd to September 24th, 2026. This year, we are officially adopting the “Global” moniker to reflect our growing international community and the many regional ROSCons happening worldwide.

Submission Deadlines

• Workshops: Due by Sun, Apr 5, 2026 12:00 AM UTC. Submit via Google Form
• Talk Proposals: Due by Sun, Apr 26, 2026 12:00 AM UTC Submit via HotCRP
• Birds of a Feather (BoF): Due by Fri, Jul 24, 2026 12:00 AM UTC, submissions opening soon.

Important Dates

• Diversity Scholarship Deadline: Sun, Mar 22, 2026 12:00 AM UTC Submit here
• Workshop Acceptance Notification: Tue, May 12, 2026 12:00 AM UTC
• Ticket Sales Begin: Mon, May 11, 2026 12:00 AM UTC
• Presentation Acceptance Notification: Tue, Jun 9, 2026 12:00 AM UTC

Diversity Scholarship Program

If you require financial assistance to attend ROSCon Global and meet the qualifications, please apply for our Diversity Scholarship Program. Thanks to our sponsors, scholarships include complimentary registration, four nights of hotel accommodation, and a travel stipend.

The deadline for the scholarship is Sun, Mar 22, 2026 12:00 AM UTC, which is well before the CFP deadlines to allow for travel planning and visa processing.

What are we looking for?

The core of ROSCon is community-contributed content. We are looking for:

• Workshops: Participatory, interactive experiences (Day 1).
• Presentations: Technical talks (10-30 minutes) on new tools, libraries, or novel applications.
• Birds of a Feather: Self-organized meetings for specific interest groups (e.g., medical robotics, space, or debugging).

We want to see your robots! Whether it is maritime robots, lunar landers, or industrial factory fleets, we want to hear the technical lessons you learned. We encourage original content, high-impact ideas, and, as always, a focus on open-source availability.

How to Prepare

If you are new to ROSCon we recommend reviewing the archive of previous talks. You are also welcome to use this Discourse thread to workshop your ideas and find collaborators.

Questions and concerns can be directed to the ROSCon Executive Committee (roscon-2026-ec@openrobotics.org) or posted in this thread. We look forward to seeing the community in Toronto!

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I’m happy to introduce PlotJuggler Bridge, a lightweight server that exposes ROS 2 or DDS topics over WebSocket, allowing remote tools like PlotJuggler to access telemetry without directly participating in the middleware network.

In many robotics setups, accessing telemetry from another computer is harder than it should be. DDS discovery over WiFi can be unreliable, opening DDS networks outside the robot can create configuration issues, and installing a full ROS 2 environment on every machine used for debugging is often inconvenient.

PlotJuggler Bridge solves this by acting as a gateway between the middleware network and external clients.
It runs close to the robot, reads the topic data, and exposes it through a simple WebSocket endpoint that any client can connect to.

This approach keeps the ROS/DDS network local while making telemetry easily accessible from other machines.

The project is available here:

Why it is useful

This is especially helpful in scenarios such as:

• monitoring a robot remotely over WiFi
• accessing telemetry from Windows or macOS machines without ROS installed
• avoiding DDS discovery and networking configuration issues
• debugging systems without exposing the full middleware network
• connecting tools without needing message definitions compiled locally

Because the bridge performs runtime schema discovery, clients can access topics even if they use custom ROS messages, without requiring those message packages to be installed on the client machine.

The bridge also aggregates and optionally compresses data, which helps reduce bandwidth usage and improves stability when streaming telemetry over wireless networks.

Main features

PlotJuggler Bridge includes several features designed for real-world robotics workflows:

• WebSocket access through a single endpoint
• automatic runtime discovery of topic schemas
• support for custom ROS message types without client-side compilation
• aggregation of messages for efficient streaming
• optional ZSTD compression
• support for multiple simultaneous clients
• bandwidth-friendly handling of large messages by stripping large array fields while preserving useful metadata

How it works

ROS 2 / DDS -> PlotJuggler Bridge -> WebSocket -> PlotJuggler

The bridge subscribes to topics in the ROS/DDS network and exposes them through a WebSocket server.
External tools can connect and receive the streamed telemetry without joining the middleware network.

Quick to start

The bridge can typically be up and running in less than 5 minutes.

Setup instructions are available in the repository README:

You will need PlotJuggler 3.16 or newer, which includes the WebSocket client plugin:

Basic usage

Once the bridge is running, the workflow is straightforward:

1. Start the bridge on the machine connected to the ROS/DDS network.
2. Open PlotJuggler on any computer.
3. Connect to the WebSocket Client using the bridge address.

The available topics will be discovered automatically and can be inspected immediately.

About the work

My name is Álvaro Valencia, and I am currently working on PlotJuggler as an intern while finishing the last months of my Robotics Software Engineering degree.

I collaborate closely with @facontidavide on this project. PlotJuggler clearly reflects years of work, effort and passion, and contributing to it is a great experience.

Together we are developing the components required to make this new Robot → PlotJuggler connection workflow simple and practical to use. The goal is to make remote telemetry access easier while keeping the system flexible for future extensions that will appear in upcoming PlotJuggler developments.

And stay tuned… more interesting things are coming soon for PlotJuggler.

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Let’s Explore Nero – Moveit2 Edition (Part I)

As a next-generation robot operating system, ROS2 provides powerful support for the intelligent and modular development of robotic arms. As the core motion planning framework in the ROS2 ecosystem, MoveIt2 not only inherits the mature functions of MoveIt but also achieves significant improvements in real-time performance, scalability, and industrial applicability.

Taking a 7-DoF robotic arm as an example, this document provides step-by-step instructions for configuring and generating a complete MoveIt2 package from a URDF model using the MoveIt Setup Assistant, enabling motion planning and visual control. This guide offers a clear, practical workflow for both beginners and developers looking to quickly integrate models into MoveIt2.

Abstract

Exporting MoveIt Package from URDF

Tags

ROS2, moveit2, Robotic Arm, nero

Repository

• Navigation Repository: GitHub - agilexrobotics/Agilex-College: Agilex College · GitHub
• Project Repository: https://github.com/agilexrobotics/piper/piper_moveit2.git

Environment

OS: Ubuntu 22.04
ROS Distro: Humble

Introduction to MoveIt2

MoveIt2 is the next-generation robotic arm motion planning and control framework developed based on the ROS2 architecture. It can be understood as a comprehensive upgrade of MoveIt in the ROS2 ecosystem. Inheriting the core capabilities of MoveIt, it has made significant improvements in real-time performance, modularity, and industrial application scenarios.

The main problems solved by MoveIt2 include:

• Robotic Arm Motion Planning
• Collision Checking
• Inverse Kinematics (IK)
• Trajectory Generation and Execution
• RViz Visualization and Interaction

Installing Moveit2

You can directly install using binary packages; use the following commands to install all components related to moveit:

sudo apt install ros-humble-moveit*

Downloading the URDF File

First, create a new workspace and download the URDF model:

mkdir -p ~/nero_ws/src
cd ~/nero_ws/src
git clone https://github.com/agilexrobotics/piper_ros.git -b humble_beta1
cd ..
colcon build 

After successful compilation, use the following command to view the model in rviz:

cd ~/nero_ws/src
source install/setup.bash
ros2 launch nero_description display_urdf.launch.py 

Exporting the MoveIt Package Using Setup Assistant

Launch the moveit_setup_assistant:

roslaunch moveit_setup_assistant setup_assistant.launch

Select Create New Moveit Configuration Package to create a new MoveIt package, then load the robotic arm.

Calculate the collision model; for a single arm, use the default parameters.

Skip selecting virtual joints and proceed to define planning groups. Here, we need to create two planning groups: the arm planning group and the gripper planning group. First, create the arm planning group; set Group Name to arm, use KDL for the kinematics solver, and select RRTstar for OMPL Planning.

Setting the Kin.Chain

Add the control joints for the planning group, select joint1~joint7, click >, then save.

Planning group creation completed.

Setting the Robot Pose; you can pre-set some actions for the planning group here.

Skip End Effectors and Passive Joints, and add interfaces in the URDF.

Setting the controller, here we use position_controllers.

Simulation will generate a URDF file for use in Gazebo, which includes physical properties such as joint motor attributes.

After configuration, fill in your name and email.

Set the package name, then click Generate Package to output the function package.

Launching the MoveIt Package

cd ~/nero_ws/src
source install/setup.bash
ros2 launch nero_moveit2_config demo.launch.py

After successful launch, you can drag the marker to preset the arm position, then click Plan & Execute to control the robotic arm movement.

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Hey Open Robotics folks

So I built a small tool called ros2_info.
The idea was simple: what if fastfetch, but for your entire ROS2 environment?

One command → instant snapshot of everything happening in your ROS2 setup.

What it shows:
• ROS2 distro + whether it’s LTS or nearing EOL
• Live nodes, topics, services, and actions
• Auto-detects which DDS middleware you’re running
• All detected colcon workspaces + their build status
• Installed ROS2 packages grouped by category
• System stats (CPU, RAM, Disk)
• Pending ROS2-related apt updates
• A small web dashboard at localhost:8099

Basically the stuff I kept checking with 10 different commands… now in one place

Works across ROS2 distros: Foxy → Humble → Iron → Jazzy → Rolling

GitHub:
https://github.com/zang7777/ros2_info

Install

cd ~/ros2_ws/src
git clone https://github.com/zang7777/ros2_info.git
cd ~/ros2_ws && colcon build --symlink-install
source install/setup.bash
(best recommended) ros2 run ros2_info ros2_info --interactive
or just
ros2 run ros2_info ros2_info 

Always fun building little dev tools for the ecosystem

~"Created by roboticists, for roboticists "

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The next ROS 2 Rust Meeting will be Mon, Mar 9, 2026 2:00 PM UTC

The meeting room will be at https://meet.google.com/rxr-pvcv-hmu

In the unlikely event that the room needs to change, we will update this thread with the new info!

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Hi everyone,

I recently had the chance to attend ROSCon Japan 2025, and it was an amazing experience meeting people from the ROS community, seeing robotics demos, and learning about the latest developments in ROS.

I made a short vlog to capture the atmosphere of the event. In the video, I shared some highlights including:

• The overall environment and venue of ROSCon Japan

• Robotics demos and technology showcased by different companies

• Booths and exhibitions from robotics organizations

• Moments from the talks and presentations

It was inspiring to see how the ROS ecosystem continues to grow and how many interesting robotics applications are being developed.

If you couldn’t attend the event or are curious about what ROSCon JP looks like, feel free to check out the video.

YouTube:

A Day at ROSCon JP 2025 | Robotics Engineer Vlog

Hope you enjoy it!

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Hello ROS community,

I’d like to introduce LSEP (Light Signal Expression Protocol) — an open standard I’ve been developing for how robots communicate their internal state to nearby humans using coordinated light signals, sound, and motion cues.

The problem LSEP solves:

Every robot manufacturer currently invents their own LED patterns and sound cues. There’s no shared vocabulary. A blinking blue light could mean “charging” on one platform and “human detected” on another. With the EU AI Act (Art. 50) now requiring transparency for human-facing AI systems, the industry needs a standardized approach.

What LSEP defines:

- 6 core states: IDLE, AWARENESS, INTENT, CARE, CRITICAL, THREAT

- 3 extended states: MED_CONF, LOW_CONF, INTEGRITY (for sensor uncertainty and self-diagnostics)

- Each state maps to specific light color + pulse pattern, optional sound, and motion modifier

- State transitions driven by Time-to-Contact (TTC) physics, not heuristics

- 1.5m proximity floor: any human within 1.5m triggers minimum AWARENESS

Technical details:

- RFC style specification (v2.0)

- Machine readable JSON signal definitions

- Unity prototype (HDRP) with 74 tests, including sensor noise simulation and tracking dropouts

- MIT licensed — use it however you want

Why I’m posting here:

ROS is where robot software gets built. If LSEP is going to be useful, it needs to work in your stacks — as a ROS node, a topic publisher, or a behavior tree integration. I’m looking for:

1. Feedback on the state model — Do 9 states cover the scenarios you encounter? What’s missing?

2. Integration ideas — How would you want to consume LSEP in a ROS 2 pipeline? As a `/lsep_state` topic? A lifecycle node?

3. Real-world edge cases — What breaks first when you imagine deploying this on your robot?

Links:

- Specification + demo: [lsep.org](https://lsep.org)

- GitHub: [ GitHub - NemanjaGalic/LSEP: Open protocol for standardized human-robot communication — 9 states, 3 modalities, 1 grammar. Physics-based. EU AI Act ready. · GitHub ]( GitHub - NemanjaGalic/LSEP: Open protocol for standardized human-robot communication — 9 states, 3 modalities, 1 grammar. Physics-based. EU AI Act ready. · GitHub )

Happy to answer questions and discuss. The goal is to make this the “USB-C of robot communication” — one standard, every platform.

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Rover + LiDAR inside a Forest3D-generated world (Gazebo Harmonic)

A quick demonstration of spawning a robot and running LiDAR perception inside a Forest3D-generated environment with realistic visuals, making it a solid base for mapping and navigation tasks.

Watch on YouTube

Performance can be improved by tuning the mesh decimation level depending on your use case.

Current work: Integrating terramechanics for more realistic rover-terrain interaction,

Forest3D supports a variety of environments beyond forests, including lunar and other unstructured terrains. Feel free to reach out

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Please come and join us for this coming meeting at Mon, Mar 9, 2026 4:00 PM UTC→Mon, Mar 9, 2026 5:00 PM UTC, where we plan to continue deploying an example Canonical Observability Stack (COS) instance based on information from the tutorials and documentation. This session will pick up where the last session left off: an AWS instance hosting the COS server side, and a VirtualBox VM hosting the robot side.

Last session, we started working through the documentation for setting up both a COS server instance and a robot instance. Unfortunately, the recording cut out shortly into the meeting due to lack of disk space. After this point, we switched to hosting in AWS and were able to host a COS instance, although it was misconfigured and the robot was unable to connect. If you’re interested to watch the recorded part of the meeting, it 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 all,

We’re building an ROV using Pixhawk (ArduSub) with a Raspberry Pi companion computer (ROS2 + MAVROS). The vehicle needs to attach and operate along vertical surfaces, so maintaining controlled roll while maneuvering is a core requirement.

Stack

• Pixhawk running ArduSub

• Companion computer: Raspberry Pi (ROS2 + MAVROS)

• Joystick control

• No external XY positioning (no DVL / external localization)

Goal

We want joystick-based control similar to POSHOLD stability, but still allow roll control so the vehicle can move along the surface while attached.

Thanks in advance — happy to share more details about the vehicle config if helpful.

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Hi everyone,

We’re curious — does a dedicated working group (or similar community) already exist for maintaining and operating ROS 2-based robots in industrial environments? If not, maybe it’s time to build one.

At Siemens, our ROS 2 efforts are focused on four key challenges:

• Shipping — How do you bring ROS 2-based systems into real industrial deployments?
• Debugging — How do you quickly find bugs when your machine runs not just ROS 2, but also PLCs, HMIs, network switches, safety sensors, and more?
• Updates — How do you keep your software reliably up to date?
• Fleet health — How do you detect critical bugs locally and across your entire fleet?

We’d love to connect with the community and learn what’s already out there!

We’re actively looking to engage with others working in this space — whether you’re building solutions, facing the same challenges, or have already found answers we haven’t discovered yet.

Here are some data points we’ve gathered so far:

Exciting tools that just dropped

The community has been busy! A few noteworthy new tools:

• Mosaico + PlotJuggler — Synchronized, reliable data pipelines
• ros2_medkit — Diagnostics and health monitoring for ROS 2
• OpenTelemetry for ROS — Observability tooling for robotic systems

Big shoutout to @doisyg for sharing impressive insights on how they manage upgrades across a large fleet of robots in the field!
And I am sure there is a big vast of further open source tools out there that can help all of us.

What Siemens has shared so far (all talks in English)

We’ve been open about our own challenges and learnings:

• Introduction to the problem space
• Bridging ROS and industrial automation — the hard parts
• Scaling up: generating BT nodes, documentation & OSS tooling

Our concrete question to you:

Would you be interested in joining a regular working group to discuss these topics and align our open-source efforts?

Vote below — even a single click tells us a lot!

• ← click me, if you are interested.

Click to view the poll.

Let’s build in the open — together!

We’re strong believers in open collaboration. Whether you’re a researcher, developer, or industry practitioner — let’s align our efforts and avoid reinventing the wheel.

A few things we’d especially love to hear about:

• Open EU calls related to these topics — always happy to explore funding opportunities and collaborative projects
• Bachelor & Master thesis requests from EU students — if you’re looking for a meaningful, real-world topic in this space, reach out! We’d love to support the next generation of robotics engineers

Cheers from Germany
Florian

Update as of Tue, Mar 3, 2026 11:00 PM UTC

Let’s try to ball point where a potential virtual meeting could already happen:
(Please also vote if the day does not fit, right now I am more interested in finding the right time of day)

• Tue, Mar 10, 2026 7:30 AM UTC
• Tue, Mar 10, 2026 10:00 AM UTC
• Tue, Mar 10, 2026 1:00 PM UTC
• Tue, Mar 10, 2026 4:00 PM UTC

Click to view the poll.

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We are pleased to officially announce ROS Meetup Medellín 2026, a space designed to bring together the robotics, ROS, and autonomous systems community in Colombia.

April 29 – Universidad EIA (Poster Session)
April 30 – Parque Explora (Talk Session)

Medellín, recognized for its strong innovation and technology ecosystem, will be the perfect setting to connect academia, industry, and the open-source community around ROS and robotics.

Call for Speakers open
Call for Posters open
Attendee registration available

If you are developing ROS-based projects, conducting robotics research, or building AI-driven and autonomous systems solutions, we invite you to share your work and actively participate in the event.

Find all the information and registration links here:
https://linktr.ee/IEEE_RAS_Colombia

We look forward to having you join us in this edition and to continue strengthening the ROS community in Colombia.

See you in Medellín

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Hello ROS Community,

MAHE Mobility Challenge 2026 is a national-level hybrid hackathon hosted by CEAM and the Department of ECE at Manipal Institute of Technology (MIT), Bengaluru.

This challenge is designed for B.Tech students passionate about autonomous and connected mobility systems, offering an opportunity to ideate, design, and build real working prototypes addressing next-generation mobility challenges.

Total Prize Pool: ₹3 Lakhs

Challenge Tracks

• AI in Mobility
Intelligent perception systems, predictive modeling, adaptive routing, autonomy stacks

• Robotics & Control
Embedded systems, actuator integration, simulation workflows, control architecture design

• Cybersecurity for Mobility
Secure V2X communication, threat modeling, safety-focused system hardening for connected vehicles

Format & Timeline

• Registrations Close: 15 March 2026

• Round 1: Online technical proposal submission (Deadline: 31 March 2026)

• Round 2: Offline prototype demonstration at MIT Bengaluru (17 April 2026)

Shortlisted teams will build and demonstrate working prototypes during the final round.

Participants are encouraged to leverage open-source robotics frameworks (ROS), simulation environments, and modular autonomy architectures where relevant.

We welcome engagement from students and robotics enthusiasts interested in contributing to secure and intelligent mobility systems.

Further details and registration:
https://mahemobility.mitblr.org/

Looking forward to participation and discussion from the ROS community.

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Introduction:

SIPA (Spatial Intelligence Physical Audit) is a trajectory-level physical consistency diagnostic. It does not require source code access or internal simulator states and directly audits 7-DoF CSV trajectories. By design, SIPA is compatible with any system that produces spatial motion data. Its principle is based on the Non-Associative Residual Hypothesis (NARH).

1. What SIPA Can Audit

SIPA operates on the final motion output, enabling post-hoc physical forensics for:

• Physics Simulators: NVIDIA Isaac Sim, MuJoCo, PyBullet, Gazebo.

• Neural World Models: World Labs Marble, OpenAI Sora, Runway Gen-3 (via pose extraction).

• Robotic Foundation Models: Any system outputting 7-DoF trajectories.

• Real-World Capture: OptiTrack, Vicon, or SLAM-based motion sequences.

Supported Data Pathways:

• Tier 1 — Native Spatial Intelligence (Recommended): High-fidelity data from Isaac Sim, MuJoCo, or Robot Telemetry.

• Tier 2 — Structured World Generators: Emerging models like World Labs Marble, where 3D states are programmable and exportable.

• Tier 3 — Pixel Video Models (Experimental): Pure video generators (Sora, Kling). This requires an additional pose-lifting step (Video \\to Pose \\to SIPA) and is currently research-grade due to vision uncertainty.

2. The Logic: Non-Associative Residual Hypothesis (NARH)

NARH posits that physical inconsistency stems from discrete solver ordering rather than just algebraic error.

(1)Setting

Consider a rigid-body simulation system defined by:

• State space S \subset \mathbb{R}^n

• Associative update operator \Phi \Delta t : S \to S

• Parallel constraint resolution composed of sub-operators `\{\Psi_i\}_{i=1}^k`

  ​The simulator implements a discrete update:

where � is an execution order induced by:

• constraint partitioning

• thread scheduling

• contact batching

• solver splitting

Each \Psi_i is individually well-defined, but their composition order may vary.

(2) Order Sensitivity

Although each operator Ψi belongs to an associative algebra (e.g., matrix multiplication, quaternion composition), the composition of numerically approximated operators may satisfy:

due to:

• finite precision arithmetic

• projection steps

• iterative convergence truncation

• asynchronous execution

Define the discrete associator:

(3) Definition: Non-Associative Residual

We define the Non-Associative Residual (NAR) at state s_t as:

R_t = \lVert A(a,b,c; s_t) \rVert

for a chosen triple of sub-operators representative of contact or constraint updates.

This residual measures path-dependence induced by discrete solver ordering, not algebraic non-associativity of the state representation.

(4) Hypothesis (NARH)

In high-interaction-density regimes (e.g., contact-rich robotics, high-speed manipulation), the Non-Associative Residual R_t becomes non-negligible relative to scalar stability metrics, and accumulates over time as a structured drift term.

Formally, there exists a regime such that:

\sum_{t=0}^{T} R_t \not\approx 0

even when:

\Vert s_{t+1} - s_t \Vert remains bounded.

(5) Interpretation

This hypothesis does not claim:

• that simulators are mathematically invalid,

• that associative algebras are incorrect,

• or that hardware tiling causes topological inconsistency.

Instead, it asserts:

Discrete parallel constraint resolution introduces a measurable order-dependent residual that is not explicitly encoded in the state space.

This residual may contribute to:

• sim-to-real divergence,

• policy brittleness,

• instability under reordering of equivalent control inputs.

(6) Falsifiability

NARH is falsified if:

1. s_t remains within numerical noise across interaction densities.

2. Reordering constraint application yields statistically indistinguishable trajectories.

3. Scalar metrics (e.g., kinetic energy norm, velocity norm) detect instability earlier or equally compared to any associator-derived signal.

(7) Research Implication

If validated, NARH suggests that:

• Order sensitivity is a structural property of discrete solvers.

• Additional diagnostic signals (e.g., associator magnitude) may serve as early-warning indicators.

• Embodied AI training in simulation may implicitly depend on hidden order-stability assumptions.

If invalidated, the experiment establishes an empirically order-invariant regime — a valuable boundary characterization of solver behavior.

3. Physical Integrity Rating (PIR)

SIPA introduces the Physical Integrity Rating (PIR), a heuristic composite indicator designed to quantify the causal reliability of motion trajectories. PIR evaluates whether a world model is “physically solvent� or accumulating “kinetic debt.�

The Metric

• Q_{\text{data}} (Data Quality): Measures input integrity (SNR, normalization, temporal jitter).

• D_{\text{phys}} (Physical Debt): Log-normalized residual derived from the Octonion Associator, testing the NARH limits.

• PIR \in [0, 1]: Higher indicates higher physical fidelity.

Credit Rating Scale

Note on Early Adoption: Since its initialization, we’ve observed a unique anomaly: 120 institutional entities cloned the repo via CLI with near-zero web UI traffic. This suggests that the industry (Sim-to-Real teams and Tech DD leads) is already utilizing NARH for internal audits. View Traffic Evidence

Call to Action

We invite the ROS community to stress-test their simulators and world models using SIPA. Any questions can be discussed under this topic!

GitHub Repository: https://github.com/ZC502/SIPA.git

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NVIDIA Isaac ROS 4.2 for DGX Spark is now live.

Here’s what’s new in 4.2:

• DGX Spark support – Build and run Isaac ROS workloads directly on DGX Spark.
• JetPack 7.1 + Jetson T4000 – Latest JetPack and Jetson T4000 support for higher-performance edge and robotics AI.
• Improved visual mapping & localization – Better visual map creation and localization, including hand-held camera workflows.
• FoundationStereo v2 – New support for higher-quality learned stereo depth.
• New sim-to-real tutorial – Gear assembly example: train insertion in sim, deploy on a UR10e arm.

Check out the full Isaac ROS 4.2 details and share what you build with this release.

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Controlling the Nero Robotic Arm with OpenClaw

As a popular open-source project, OpenClaw has become a highlight in the robotic arm control field with its intuitive operation and strong adaptability. It enables full end-to-end linkage between AI commands and device execution, greatly lowering the barrier for robotic arm control. This article focuses on practical implementation. Combined with the pyAgxArm SDK, we will guide you through the download, installation, and configuration of OpenClaw to achieve efficient control of the NERO 7-axis robotic arm.

Seamless AI Control: AgileX NERO 7-DoF Arm with OpenClaw

Download and Install OpenClaw

• Open the OpenClaw official website: https://openclaw.ai/
• Locate the Quick Start tab and execute the one-click installation script

Start Configuring OpenClaw

• It is recommended to select the QWEN model

• Select all hooks

• Open the web interface

Teach OpenClaw the Skill and Rules for Controlling the Robotic Arm

• Create an agx_arm_codegen directory in the skill folder, then create the following skill files:

• SKILLS.md

---
name: agx-arm-codegen
description: Guide OpenClaw to generate pyAgxArm-based robotic arm control code from user natural language. When users describe robotic arm movements with prompts and existing scripts cannot directly meet the requirements, automatically organize and generate executable Python scripts based on the APIs and examples provided by this skill.
metadata:
  {
    "openclaw":
      {
        "emoji": "烙",
        "requires": { "bins": ["python3", "pip3"] },
      },
  }
---

## Function Overview

- This skill is used to **guide OpenClaw to generate** executable pyAgxArm control code (Python scripts) based on user natural language descriptions, rather than just calling existing CLIs.
- Reference SDK: pyAgxArm ([GitHub](https://github.com/agilexrobotics/pyAgxArm)); Reference example: `pyAgxArm/demos/nero/test1.py`.

## When to Use This Skill

- Users say "Write code to control the robotic arm", "Generate a control script based on my description", "Make the robotic arm perform multiple actions in sequence", etc.
- Users explicitly request to "generate Python code" or "provide a runnable script" to control AgileX robotic arms such as Nero/Piper.

## Generate Code Using This Skill
   - Based on user prompts, combine the APIs and templates in `references/pyagxarm-api.md` of this skill to generate a complete, runnable Python script.
   - After generation, explain: the script needs to run in an environment with pyAgxArm and python-can installed, and CAN must be activated and the robotic arm powered on; remind users to pay attention to safety (no one in the workspace, small-scale testing first is recommended).

## Rules for Generating Code

1. **Connection and Configuration**
   - Use `create_agx_arm_config(robot="nero", comm="can", channel="can0", interface="socketcan")` to create a configuration (Nero example; Piper can use `robot="piper"`).
   - Use `AgxArmFactory.create_arm(robot_cfg)` to create a robotic arm instance, then `robot.connect()` to establish a connection.
2. **Enabling and Pre-Motion**
   - CRITICAL: The robot MUST BE ENABLED before switching modes. If the robot is in a disabled state, you cannot switch modes.
   - Switch to normal mode before movement, then enable: `robot.set_normal_mode()`, then poll `robot.enable()` until successful; you can set `robot.set_speed_percent(100)`.
   - Motion modes: Whenever using move_* or needing to switch to * mode, explicitly set `robot.set_motion_mode(robot.MOTION_MODE.J)` (Joint), `P` (Point-to-Point), `L` (Linear), `C` (Circular), `JS` (Joint Quick Response, use with caution).
3. **Motion Interfaces and Units**
   - Joint motion: `robot.move_j([j1, j2, ..., j7])`, unit is **radians**, Nero has 7 joints.
   - Cartesian: `robot.move_p(pose)` / `robot.move_l(pose)`, pose is `[x, y, z, roll, pitch, yaw]`, position unit is **meters**, attitude is **radians**.
   - Circular: `robot.move_c(start_pose, mid_pose, end_pose)`, each pose is 6 floating-point numbers.
   - CRITICAL: All movement commands (move_j, move_js, move_mit, move_c, move_l, move_p) must be used in normal mode
   - After motion completion, poll `robot.get_arm_status().msg.motion_status == 0` or encapsulate `wait_motion_done(robot, timeout=...)` before executing the next step.
4. **Mode Switching**
   - Switching modes (master, slave, normal) requires 1s delay before and after the mode switch
   - Use `robot.set_normal_mode()` to set normal mode
   - Use `robot.set_master_mode()` to set master mode
   - Use `robot.set_slave_mode()` to set slave mode
   - CRITICAL: Enable the robot FIRST with `robot.enable()` BEFORE switching modes
5. **Safety and Conclusion**
   - In the generated script, note: confirm workspace safety before execution; small-scale movement is recommended for the first time; use physical emergency stop or `robot.electronic_emergency_stop()` / `robot.disable()` in case of emergency.
   - If the user requests "disable after completion", call `robot.disable()` at the end of the script.
6. **Implementation Details**
   - When waiting for motion to complete, use shorter timeout (2-3 seconds)
   - After each mechanical arm operation, add a small sleep (0.01 seconds)
   - Motion completion detection: `robot.get_arm_status().msg.motion_status == 0` (not == 1)

## Reference Files

- **API and Minimal Runnable Template**: `references/pyagxarm-api.md`  
  When generating code, refer to the interfaces and code snippets in this file to ensure consistency with pyAgxArm and test1.py usage.

## Safety Notes

- The generated code will drive a physical robotic arm. Users must be reminded: confirm no personnel or obstacles in the workspace before execution; it is recommended to test with small movements and low speeds first.
- High-risk modes (such as `move_js`, `move_mit`) should be marked with risks in code comments or user explanations, and it is recommended to use them only after understanding the consequences.
- This skill is only responsible for "guiding code generation" and does not directly execute movements; users need to prepare the actual running environment, CAN activation, and pyAgxArm installation by themselves (refer to environment preparation in the agx-arm skill).

• pyagxarm-api.md

# pyAgxArm API Quick Reference & Minimal Runnable Template

For reference when OpenClaw generates robotic arm control code from user natural language. SDK source: pyAgxArm ([GitHub](https://github.com/agilexrobotics/pyAgxArm)); Example reference: `pyAgxArm/demos/nero/test1.py`.

## 1. Connection and Configuration

```python
from pyAgxArm import create_agx_arm_config, AgxArmFactory

# Configuration: robot options - nero / piper / piper_h / piper_l / piper_x; channel e.g. can0
robot_cfg = create_agx_arm_config(
    robot="nero",
    comm="can",
    channel="can0",
    interface="socketcan",
)
robot = AgxArmFactory.create_arm(robot_cfg)
robot.connect()

• create_agx_arm_config(robot, comm="can", channel="can0", interface="socketcan", **kwargs): Create configuration dictionary; CAN-related parameters are passed via kwargs (e.g. channel, interface).
• AgxArmFactory.create_arm(config): Return robotic arm driver instance.
• robot.connect(): Establish CAN connection and start reading thread.

2. Enabling and Modes

robot.set_normal_mode()   # Normal mode (single arm control)
# Enable: poll until successful
while not robot.enable():
    time.sleep(0.01)

robot.set_speed_percent(100)   # Motion speed percentage 0–100
# Disable
while not robot.disable():
    time.sleep(0.01)

• Master/Slave modes (Nero/Piper, etc.): robot.set_master_mode() (zero-force teaching), robot.set_slave_mode() (follow master arm).

3. Motion Modes and Interfaces

• Units: Joint angles are in radians; Cartesian pose is in meters (x,y,z) and radians (roll, pitch, yaw).
• Nero has 7 joints; Piper has 6 joints, the number of parameters for move_j/move_js must match the model.

Example (Joint Motion + Wait for Completion):

import time

def wait_motion_done(robot, timeout: float = 3.0, poll_interval: float = 0.1) -> bool:  # Shorter timeout (2-3s)
    time.sleep(0.5)
    start_t = time.monotonic()
    while True:
        status = robot.get_arm_status()
        if status is not None and getattr(status.msg, "motion_status", None) == 0:
            return True
        if time.monotonic() - start_t > timeout:
            return False
        time.sleep(poll_interval)

robot.set_motion_mode(robot.MOTION_MODE.J)
robot.move_j([0.01, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0])
wait_motion_done(robot, timeout=3.0)  # Shorter timeout

4. Read Status

• robot.get_joint_angles(): Current joint angles (return value is array when with .msg attribute).
• robot.get_flange_pose(): Current flange pose [x, y, z, roll, pitch, yaw].
• robot.get_arm_status(): Motion status, etc.; status.msg.motion_status == 0 indicates motion completion.
• Note: Detect motion completion with robot.get_arm_status().msg.motion_status == 0 (not == 1)

5. Others

• Homing: robot.move_j([0] * 7) (7 joints for Nero).
• Emergency Stop: robot.electronic_emergency_stop(); recovery requires robot.reset().
• MIT Impedance/Torque Control (Advanced): robot.set_motion_mode(robot.MOTION_MODE.MIT), robot.move_mit(joint_index, p_des, v_des, kp, kd, t_ff), parameter ranges refer to SDK, use with caution.

6. Minimal Runnable Template (Extend based on this when generating code)

#!/usr/bin/env python3
import time
from pyAgxArm import create_agx_arm_config, AgxArmFactory


def wait_motion_done(robot, timeout: float = 3.0, poll_interval: float = 0.1) -> bool:  # Shorter timeout (2-3s)
    time.sleep(0.5)
    start_t = time.monotonic()
    while True:
        status = robot.get_arm_status()
        if status is not None and getattr(status.msg, "motion_status", None) == 0:
            return True
        if time.monotonic() - start_t > timeout:
            return False
        time.sleep(poll_interval)


def main():
    robot_cfg = create_agx_arm_config(
        robot="nero",
        comm="can",
        channel="can0",
        interface="socketcan",
    )
    robot = AgxArmFactory.create_arm(robot_cfg)
    robot.connect()

    # Mode switching requires 1s delay before and after
    time.sleep(1)  # 1s delay before mode switch
    robot.set_normal_mode()
    time.sleep(1)  # 1s delay after mode switch
    
    # CRITICAL: The robot MUST BE ENABLED before switching modes
    while not robot.enable():
        time.sleep(0.01)
    robot.set_speed_percent(80)

    # After each mechanical arm operation, add a small sleep (0.01 seconds)
    # CRITICAL: All movement commands must be used in normal mode
    robot.set_motion_mode(robot.MOTION_MODE.J)
    robot.move_j([0.05, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0])
    time.sleep(0.01)  # Small delay after move command
    wait_motion_done(robot, timeout=3.0)  # Shorter timeout

    # Optional: Disable before exit
    # while not robot.disable():
    #     time.sleep(0.01)


if __name__ == "__main__":
    main()

When generating code, replace or add motion steps (move_j / move_p / move_l / move_c, etc.) according to user descriptions, and keep consistency in connection, enabling, wait_motion_done and units (radians/meters).

• Next, teach OpenClaw this skill

After configuring the robotic arm CAN communication and Python environment, OpenClaw can automatically call the SDK driver to generate control code and control the robotic arm

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Hi everyone!

LinkForge v1.3.0 was just released! But more than a release announcement, I want to take a moment to share the bigger vision of where this project is going — because it’s grown far beyond a Blender plugin.

The Vision

LinkForge is not just a URDF exporter for Blender. The architecture is intentionally built as a Hexagonal Core, fully decoupled from any single 3D host or output format.

The mission is simple:

Bridge the gap between creative 3D design and high-fidelity robotics engineering.

Design Systems (Blender, FreeCAD, Fusion 360) ➜ LinkForge Core ➜ Simulation & Production (ROS 2, MuJoCo, Gazebo, Isaac Sim)

Because in robotics, Physics is Truth. Every inertia tensor, every joint limit, every sensor placement should be mathematically correct before it ever reaches a simulator.

What’s New in v1.3.0?

Full release notes on GitHub

Performance

• Depsgraph caching and NumPy-accelerated inertia calculations for large robots

• Formal Kinematic Graph engine for cycle detection and topology validation

ros2_control Intelligence

• Joint sync, XACRO modularity improvements, and 100% core test coverage for the control pipeline

• ros2_control hardware interfaces now auto-generated from the dashboard with enhanced joint model (safety/calibration support)

Key Bug Fixes

• Resolved XACRO import failures for ros2-style robot descriptions (e.g., $(find pkg)/... macro resolution)

• Robust mesh import cleanup and improved XACRO empty-placeholder pruning

Component Search

• Added a component search filter to the component browser — makes large, multi-link robots much easier to navigate

Looking for Contributors

The upcoming roadmap includes SRDF Support, the linkforge_ros package, and a Composer API for modular robot assemblies.

If you work in ROS 2, enjoy Python or Rust, or have ideas on how to improve the URDF/XACRO workflow, come say hi:

• GitHub Repository

• Documentation

• Downloads on Blender

What is your biggest URDF/XACRO pain point today? I’d love to know what the community needs most as we plan the next milestone!

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We are excited to share news about the next monthly meeting of the Boston Robot Hackers! Check it out If you are in the Boston area and please register for the event.

Where: Artisans Asylum, 96 Holton Street, Boston, MA 02135
When: Thursday March 5, 7:00-9:00pm
Speaker: Tom Ryden of Mass Robotics

If you are into Robotics (and, by definition, you are, given you are reading this!) this promises to be a very interesting talk! Tom will start with an overview of MassRobotics and then get into what the current trends are in the robotics market: what problems are start-ups addressing, how the fundraising market is today, and where the investment dollars are going.

And if you cannot make it, still consider joining our organization!

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Hi Everyone,

As you may have seen in the recent blog post, Intrinsic is joining Google as a distinct robotics and AI unit. Specifically Intrinsic’s platform will bring a new “infrastructural bridge” between Google’s frontier AI research (such as the AI coming from teams at Gemini and DeepMind) and the practical, high-stakes requirements of industrial manufacturing, which is Intrinsic’s focus. This decision will allow our team to continue building the Intrinsic platform, and operate in a very similar way to before. Our commercial mandate remains the same, as does our focus on delivering intelligent solutions for our customers.

Intrinsic remains dedicated to the commitments we’ve made to the open source community, to ROS, Gazebo and Open-RMF (including Lyrical and Kura release roadmaps) and deepening our platform integrations with ROS over time. We’re also very excited about the AI for Industry Challenge this year, which is organized with the team at Open Robotics and has thousands of registrants so far.

From the community’s perspective we are expecting minimal disruption, if any, and we look forward to showing and sharing more news at ROSCon in Toronto later this year.

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The ROS Lyrical Release Working Group will have its first meeting Fri, Feb 27, 2026 7:00 PM UTC→Fri, Feb 27, 2026 8:00 PM UTC.

Want to come? Give feedback on the time here: Meeting time: ROS Lyrical Release WG

Meeting link: https://openrobotics-org.zoom.us/meetings/81224698184/invitations?signature=SrUjwX951phQQqx25bNfAA-MFEpABNsKY1vAAWfp91s

Notes and Agenda: https://docs.google.com/document/d/1lkilmVulAUF1qVRsmimMa1cJtO2jOLoGy75itOCwc78/edit?usp=sharing

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