Vineet Rakesh

Title: Innovations by Vineet Rakesh in Non-Invasive Body Temperature Estimation

Introduction

Vineet Rakesh is an accomplished inventor based in Frederick, MD (US). He has made significant contributions to the field of physiological measurements, particularly in the estimation of human core body temperature. With a total of 2 patents to his name, Rakesh's work is paving the way for advancements in non-invasive health monitoring technologies.

Latest Patents

Rakesh's latest patents focus on real-time estimation of human core body temperature based on non-invasive physiological measurements. One of his inventions describes a method of estimating body temperature by utilizing physiological data, including heart rate, received from at least one sensor, along with environmental data. This data is input into a model on a processor, which generates an estimated body temperature and physiological condition. The processor then compares the estimated condition to a measured physiological condition, allowing for adjustments to the model when discrepancies exceed a certain threshold. Another embodiment of this invention reiterates the same principles, emphasizing the importance of accurate and real-time health monitoring.

Career Highlights

Vineet Rakesh is currently employed by the US Government as represented by the Secretary of the Army. His role involves applying his innovative ideas to enhance health monitoring systems, which are crucial for various applications, including military and civilian health assessments.

Collaborations

Rakesh has collaborated with notable colleagues such as Jaques Reifman and Srinivas Laxminarayan. Their combined expertise contributes to the development of advanced technologies in the field of physiological monitoring.

Conclusion

Vineet Rakesh's contributions to the field of non-invasive body temperature estimation highlight the potential for innovative health monitoring solutions. His work not only advances technology but also enhances the understanding of physiological conditions in real-time.