Steel Structures – Collaborative Learning with Oculus Rift

Steel Structures – Collaborative Learning with Oculus Rift

Civil & Environmental Engineering: Design of Metal Structures (CEE413) uses a cluster of Oculus Rift head-mounted displays to visualize buckling metal columns in virtual reality. The cluster is configured in the Duderstadt Center’s Jugular software so that the instructor leads a guided tour using a joystick while three students follow his navigation. This configuration allows the instructor to control movement around the virtual object while students are only able to look around.

Developed in a collaboration with the Visualization Studio, using the Duderstadt Center’s Jugular software this simulation can run on both an Oculus Rift or within the MIDEN.

An Application for Greek Transcription

An Application for Greek Transcription

Practice is the only way to learn a new language. However, when learning ancient languages, such as Greek, it can be difficult to get immediate, reliable feedback on practice work. This is why Professor Pablo Alvarez in Papyrology is working with Duderstadt Center student programmer Edward Wijaya to create an app for students to practice transcribing ancient Greek manuscripts into digital writing.

The app is divided into three modes: Professor/curator mode, student mode, and discovery mode. The professor mode allows the curator to upload a picture of the manuscript and post a line by line digital transcription of the document. These are the “answers” to the document. In student mode, these manuscript are transcribed by the students. When they click the check button, the student is given a line by line comparison to the curator’s answers. Furthermore, the discovery mode allows individuals with no Greek training to learn about the letters and read descriptions in the notations used.

A wide variety of fragile manuscripts which are often inaccessible to students are available on the app allowing the students to  gain experience with diverse handwriting and histories

Surgical Planning for Dentistry: Digital Manipulation of the Jaw

Surgical Planning for Dentistry: Digital Manipulation of the Jaw

CT data was brought into Zbrush & Topogun to be segmented and re-topologized. Influence was then added to the skin mesh allowing it to deform as the bones were manipulated.

Hera Kim-Berman is a Clinical Assistant Professor with the University of Michigan School of Dentistry. She recently approached the Duderstadt Center with an idea that would allow surgeons to prototype jaw surgery specific to patient data extracted from CT scans. Hera’s concept involved the ability to digitally manipulate portions of the skull in virtual reality, just as surgeons would when physically working with a patient, allowing them to preview different scenarios and evaluate how effective a procedure might be prior to engaging in surgery.

Before re-positioning the jaw segments, the jaw has a shallow profile.

After providing the Duderstadt Center with CT scan data, Shawn O’Grady was able to extract 3D meshes of the patient’s skull and skin using Magics. From there, Stephanie O’Malley worked with the models to make them interactive and suitable for real-time platforms. This involved bringing the skull into a software like Zbrush and creating slices in the mesh to correspond to areas identified by Hera as places where the skull would potentially be segmented during surgery. The mesh was then also optimized to perform at a higher frame rate when incorporated into real-time platforms. The skin mesh was also altered, undergoing a process called “re-topologizing” which allowed it to be more smoothly deformed.  From there, the segmented pieces of the skull were re-assembled, and then assigned influence over areas of the skin in a process called “rigging”. This allowed for areas of the skin to move with selected bones as they were separated and shifted by a surgeon in 3D space.

After re-positioning of the jaw segments, the jaw is more pronounced.

Once a working model was achieved, it was passed off to Ted Hall and student programmer Zachary Kiekover, to be implemented into the Duderstadt Center’s Jugular Engine, allowing the demo to run at large scale and in stereoscopic 3D from within the virtual reality MIDEN but also on smaller head mounted displays like the Oculus Rift. Additionally, more intuitive user controls were added which allowed for easier selection of the various bones using a game controller or motion tracked hand gestures via the Leap Motion. This meant surgeons could not only view the procedure from all angles in stereoscopic 3D, but they could also physically grab the bones they wanted to manipulate and transpose them in 3D space.

Zachary demonstrates the ability to manipulate the model using the Leap Motion.

Tour the Michigan Ion Beam Laboratory in 3D

Tour the Michigan Ion Beam Laboratory in 3D

3D Model of the Michigan Ion Beam Laboratory

The Michigan Ion Beam Laboratory (MIBL) was established in 1986 as part of the Department of Nuclear Engineering and Radiological Sciences in the College of Engineering. Located on the University of Michigan’s North Campus, the MIBL serves to provide unique and extensive facilities to support research and development. Recently, Professor Gary Was, Director of the MIBL reached out to the Duderstadt Center for assistance with developing content for the MIBL website to better introduce users to the capabilities of their lab as construction on a new particle accelerator reached completion.

Gary’s group was able to provide the Duderstadt Center with a scale model of the Ion Beam Laboratory generated in Inventor and a detailed synopsis of the various components and executable experiments. From there, the Stephanie O’Malley of the Duderstadt Center optimized and beautified the provided model, adding corresponding materials, labels and lighting. A series of fly-throughs, zoom-ins, and experiment animations were generated from this model that would serve to introduce visitors to the various capabilities of the lab.

These interactive animations were then integrated into the MIBL’s wordpress platform by student programmer, Yun-Tzu Chang. Visitors to the MIBL website are now able to compare the simplified digital replica of the space with actual photos of the equipment as well as run various experiments to better understand how each component functions.  To learn more about the Michigan Ion Beam Laboratory and to explore the space yourself, visit their website at  mibl.engin.umich.edu.