AME
Robotics & Embedded Systems Objectives
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1. Designed pulse oximeter sensor. Had it created and assembled all non-extended parts by JLC PCB. Surface mount soldered extended component myself.
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2. Schematics show the inputs and outputs of my digital logic systems to allow for the MAX30105 module to work.
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3. Created and designed a PCB and Schematics for the pulse-oximeter sensor board using a selection of an esp32.
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5. Created PCB and Schematics for the pulse-oximeter sensor. This includes advanced digital logic design, signal processing, and high-speed digital systems to communicate sensor data with esp32.
Digital Maker & Fabrication Objectives
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1. Am in the process of getting a provisional patent. Have been in communication with Mark Smith and Pacer Udall a patent lawyer Mark suggested.
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2. Created PCB and Schematics for the pulse-oximeter sensor. Using trends in design principles such as a PCB design using EsayEDA and apply them to the form and function of a pulse-oximeter device.
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6. Designed pulse oximeter sensor. Had it created and assembled all non-extended parts by JLC PCB. Surface mount soldered extended component myself.
Description:
The project A.M.E will make medical devices connect to the intranet (localized network) making them IoT and display information on a computer matrix. This information will include all test results and a notes section for each visit. Then it will display results from this visit compared to previous visits. This will allow for better and faster a diagnosis. All of this will be controlled through a gateway, so patient information isn’t leaked. I created a PCB for a pulse oximeter for my viable product for SIP.