Difference between revisions of "Kinematic Trajectory and Force Capture System"

From Healthcare Robotics Wiki
Jump to: navigation, search
(Pictures of the Setup)
(Hardware)
Line 19: Line 19:
 
[[Image:utm-servo-bracket.jpg|thumb| Image of the solidworks part for the bracket to mount the UTM on to the servo.]]
 
[[Image:utm-servo-bracket.jpg|thumb| Image of the solidworks part for the bracket to mount the UTM on to the servo.]]
 
This is the hardware setup that we use:
 
This is the hardware setup that we use:
* Tilting servo: Robotis Servo (typically we use RX-28) http://www.crustcrawler.com/motors/RX28/index.php?prod=66
+
* Camera: Point Grey DragonFly2 with remote head
* This gives a serial interface to control the servo: http://www.crustcrawler.com/electronics/USB2Dynamixel/index.php?prod=65
+
* Lens: Varifocal Video Lens 4mm - 12mm (Stock Number: NT58-365) ($150.00) [http://www.edmundoptics.com/onlinecatalog/displayproduct.cfm?productID=1620&PageNum=1&StartRow=1 link]
* Hokuyo UTM. (http://www.acroname.com/robotics/parts/R314-HOKUYO-LASER4.html)
+
* Tripod for the camera.
* Bracket to mount the Hokuyo on to the servo.
+
* Studio Lights
** This is a custom part that we have designed.
+
* Laptop: Anything that runs Ubuntu and has a firewire port. Four pin firewire port will require a hub and external power to provide power to the DragonFly.
** The solidworks CAD file ([[Media:utm-servo-bracket.sldprt|utm-servo-bracket.sldprt]]). This requires Solidworks 2009.
+
* Mount for the DragonFly: See Image and the CAD Models.
** We have taken two routes for making the bracket
+
* Hook end effector: See images and the CAD Models.
**# buy Aluminium channels from http://mcmastercarr.com and drill the appropriate holes.
+
* Checkerboard patterns: Checked into the subversion repository with all the code.
**# use http://www.mfg.com to get the part manufactured from the CAD file. Will take between a week to 10 days.
+
** We thank Abhishek Bhatkhande for making the CAD model from the bracket design.
+
* Screws:
+
** Four M2x4 (2mm diameter, 4mm length) to connect the servo to the bracket.
+
** Two M3x6 or M3x8 to connect the UTM to the bracket.
+
** Longer screws will require washers.
+
 
+
==== Power ====
+
[[Image:robotis-servo-power.jpg|thumb| Image showing how we power the Robotis servos and connect to the USB2Dynamixel converter.]]
+
The image on the right shows how we power the Robotis servos and connect to the USB2Dynamixel converter.
+
* The block labeled 12V is a power supply that takes unregulated 24V as input (red and white cables ending in a connector) and gives 12V regulated as output. Regulated power is not required for the servos but we also use the same power supply for Hokuyos and so find it convenient. RX28 servos can take between 12V and 16V (I think. Please read the manual to confirm).
+
* The output of this power block in the image is are the green (GND) and red (12V) wires.
+
* GND goes to both the USB2Dynamixel and the Robotis servo.
+
* 12V goes to the servo only. Notice that a cable on the USB2Dynamixel is clipped. This is intentional and is the one that is labeled N/C on the USB2Dynamixel. Connecting 12V to that causes the USB2Dynamixel to burn.
+
* The rest of the wiring from the USB2Dynamixel is simply straight connections for the RS485 communication.
+
 
+
==== Troubleshooting ====
+
 
+
* The RX28's communicate using RS485 protocol. Ensure that the USB2Dynamixel toggle switch is set to RS485.
+
  
 
== Code ==
 
== Code ==

Revision as of 20:29, 13 July 2010

Author

Advait Jain (http://www.cc.gatech.edu/~advait)

What this does

This page describes the capture system that we designed to log the kinematic trajectory through which mechanisms (doors and drawers) move and the forces used to operate them.

We first used this setup in this paper: The Complex Structure of Simple Devices: A Survey of Trajectories and Forces that Open Doors and Drawers. Advait Jain, Hai Nguyen, Mrinal Rath, Jason Okerman, and Charles C. Kemp. IEEE RAS/EMBS International Conference on Biomedical Robotics and Biomechatronics (BIOROB), 2010. This paper and others can be downloaded from the Heathcare Robotics Lab website (http://www.healthcare-robotics.com)


Picture of the Setup

Capture setup.jpg

Hardware

Image of the solidworks part for the bracket to mount the UTM on to the servo.

This is the hardware setup that we use:

  • Camera: Point Grey DragonFly2 with remote head
  • Lens: Varifocal Video Lens 4mm - 12mm (Stock Number: NT58-365) ($150.00) link
  • Tripod for the camera.
  • Studio Lights
  • Laptop: Anything that runs Ubuntu and has a firewire port. Four pin firewire port will require a hub and external power to provide power to the DragonFly.
  • Mount for the DragonFly: See Image and the CAD Models.
  • Hook end effector: See images and the CAD Models.
  • Checkerboard patterns: Checked into the subversion repository with all the code.

Code