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High-probability grants
According to our matching algorithm, Richard D. Gitlin is the likely recipient of the following grants.
Years |
Recipients |
Code |
Title / Keywords |
Matching score |
2010 — 2015 |
Gitlin, Richard Sun, Yu Anderson, Adam (co-PI) [⬀] |
N/AActivity Code Description: No activity code was retrieved: click on the grant title for more information |
Cps: Small: Virtually Transparent Epidermal Imagery @ University of South Florida
The objective of this research is to develop a cyber-physical system capable of displaying the in vivo surgical area directly onto patients' skin in real-time high definition. This system will give surgeons an ?x-ray? vision experience, since they see directly through the skin, and remove a spatial bottleneck and additional scarring caused by laparoscopes in minimally invasive surgery. The approach is to develop micro-cameras that: occupy no space required by surgical tools, produce no additional scarring to the patient, and transfer wireless high-definition video images. A virtual view generating system will project the panoramic videos from all cameras to the right spot on the patient?s body with geometry and color distortion compensation. A surgeon-camera-interaction system will be investigated to allow surgeons to control viewpoint with gesture recognition and finger tracking. Novel techniques will be developed for zero-latency high-definition wireless video transfer through the in vivo/ex vivo medium. Image viewpoint alignment and distortion compensation in real time will also be investigated. The results will be a potential paradigm shift in minimally invasive surgery.
The proposed work benefits the millions of surgeries capable of being performed through a single incision in the abdomen by providing virtually transparent skin to surgeons who will enjoy all the visual benefits of open-cavity surgery without all the associated risks to the patient. The goals of this research are extremely ?hands-on? and immediately applicable to outreach activities that can excite youth, minority students, and others about the science, medicine a and engineering careers.
|
0.915 |
2013 — 2015 |
Arslan, Huseyin (co-PI) [⬀] Gitlin, Richard |
N/AActivity Code Description: No activity code was retrieved: click on the grant title for more information |
Eager: Collaborative Research: Holistically Application-Aware Multi-Dimensional Cognitive Radio (Hamcr) @ University of South Florida
The overarching goal of the Holistically Application-Aware Multi-dimensional Cognitive Radio (HAMCR) research is to create a set of transformative and holistic technologies that enable substantial growth in the capacity of wireless networks, with support for diverse applications, but without increasing the available spectrum. The project is based on the observation that in today's wireless networks the spectral allocation of resources is either independent of the applications' Quality of Service (QoS) requirements and of the user's perceived QoS, or at best relies on a set of pre-defined fixed priorities. HAMCR maximizes spectrum utilization by trading off the spectral resource allocations of connections for the application-level QoS, while still maintaining acceptable levels of QoS for the individual users of the underlying applications, thus satisfying an increased number of users in times of shortage of spectral resources. Such an application-aware cognitive radio significantly advances spectrum utilization by intelligently supporting the expected traffic growth and by dynamically satisfying the changing demands in traffic. To achieve the above goal, the objectives of the proposed research are to: 1) Develop the fundamental design of middleware to optimize the allocation of the available physical resources by characterizing the applications' parameters and by trading off application-level QoS for spectral resources, while minimizing the degradation to the user-perceived QoS, thus maximizing the spectrum utilization; and 2) Design and implementation of a simulated wireless testbed to assess the feasibility of the application-based resources allocation by evaluating the complexity and the gain of the proposed approach for a number of realistic communication scenarios. The results of this project are expected to forge a new direction in the cognitive radio field, i.e., application-aware cognitive radio.
|
0.915 |