The Hexapod MK-IVS is a pre-order item with the anticipated shipping date of 10/15/2020.
Some of the specifications for the MK-IVS will be released in the coming days / weeks.
The PhantomX MK-IVS Hexapod is a six legged, ROS research platform featuring the Rasberry PI 4b and the DYNAMIXEL XL Series Smart Servos from Robotis. The MK-IV comes pre-assembled and tested and is fully supported in Ubuntu 18.04c / ROS Melodic. The platform offers wifi, tethered connection and wireless via Bluetooth / Playstation 4 Control options. The MK-IV Hexapod has a payload capacity of roughly TBD, walking speed of roughly TBD (default gait) and an estimated run time on battery of TBD minutes.
The PhantomX MK-IVS is built with 18x DYNAMIXEL XC430-W150-T Smart Servos from Robotis. The DYNAMIXEL XC-W150 is a High Performance version of the XL430 (Entry-level DYNAMIXEL), offering more torque and metal gears (instead of plastic). The XC430-W150-T has (at 11.1v) 1.6N.m stall torque, 1.4(A) stall current and a no load speed of 106 RPM. For more information on the motors click here.
The Hexapod comes in both shelled and unshelled variations (the unshelled version does not contain the neopixel eyes feature to inform users of current state of the hexapod).
ROS Packages & Support
Supported on Ubuntu 18.04 with ROS Melodic Packages include full meshes and URDFs (including accurate inertial models), driver node that controls the physical robot and publishes joint states as well as gazebo and moveit support. Examples are also included to show users how the core packages work.
RASPBERRY PI 4B
The Raspberry PI 4 Model B features a high-performance 64-bit quad-core processor, dual-display support at resolutions up to 4k via a pair of micro-HDMI ports, hardware video decode at up to 4kp60, dual-band 2.4/5.0 GHz wireless LAN, Bluetooth 5.0, Gigabit Ethernet, USB 3.0 and PoE capability (via a separate PoE HAT add-on). The RPI4 comes with 4 GB of Ram and 32 GB Micro SD.
Move In Place
- Translate Forward / Backward
- Translate Side / Side
- Translate Up / Down
- Roll Body
- Pitch Body
- Move in place can do multiple moves simultaneously
- 3 Supported Walking Gaits
- Gazebo Simulation
- Python API
- Raspberry Pi 4B w/ 4g Ram
- PlayStation 4 Remote Control
- IRROS code structure
- 1x Hexapod MK-IVS Assembled
- 11.1v 4500 LiPo Battery
- 1x DYNAMIXEL U2D2
- 1x 12v5a Power Supply
- 1x USB2 Micro Cable
- Battery Charger
- Drivers / Extra Hardware
|Speed (MMs per second)
|Est. Run Time (Battery)
|Weight (shelled / unshelled)
Built with Industry Leading Smart Servos
The DYNAMIXEL X-Series smart servos offer features that would normally only be found on industrial level motors for a fraction of the price.
Addressable - All servos have unique IDs allowing users to easily communicate with individual servos or groups of servos. The Shadow ID feature also allows for easy control of a second servo in dual servo joints.
Daisy Chain - DYNAMIXEL servos are connected in a daisy chain (each servo plugged into the next in series) making them extremely scalable and easy to maintain.
Servo Management Software - DYNAMIXEL Wizard 2.0 allows users to configure register settings such as PID gains, Control Modes (position, velocity, current, or PWM) and others. The software also provides tools for firmware updates, diagnostics, configuration and testing, data plotting, generating & monitoring DYNAMIXEL packets, and more.
Trajectory Smoothing - Smart servos have multiple registers for setting velocity & acceleration limits, PID gains, and more for fine tuning smooth joint motions.
Low Level Libraries Provided - DYNAMIXEL servos have libraries that abstract away the serial communication layer allowing developers to concentrate their time on higher level code.
To make the lower-level actuator ROS wrappers able to be easily integrated into our higher-level code, we have developed an intuitive approach called the Interbotix Research Robotics Open Standard (IRROS). Every repository that builds on top of this contains a chart similar to the above generic one - but filled in with the specifics for each robot. There are five main layers: Hardware Layer - Describes the Physical Setup of the Robot, Driver Layer - The first software layer containing ROS wrappers for actuators & sensors, Control Layer - Software layer containing ROS packages per robot type, Application Support Layer - Provides Python modules or 'support-level' ROS packages and the Reseach Layer - The final software layer at which an end user programs their own code. For more information on IRROS click here.