https://deploy-preview-1007--ucsc-ospo.netlify.app/author/eric-vetha/Eric VethaWowchemy (https://wowchemy.com)en-ushttps://deploy-preview-1007--ucsc-ospo.netlify.app/author/eric-vetha/avatar_huab0c711414dda55ce426ab4a8a3dc3c0_18783492_270x270_fill_q75_lanczos_center.jpghttps://deploy-preview-1007--ucsc-ospo.netlify.app/author/eric-vetha/https://deploy-preview-1007--ucsc-ospo.netlify.app/project/osre25/ucsc/wadar/Wed, 05 Feb 2025 00:00:00 +0000https://deploy-preview-1007--ucsc-ospo.netlify.app/project/osre25/ucsc/wadar/<p><a href="https://github.com/jlab-sensing/wadar" target="_blank" rel="noopener">WaDAR</a> (Water Radar) is an innovative, low-cost, hybrid approach to soil moisture sensing that combines the benefits of in-ground (in situ) and remote sensing technologies. Traditional soil moisture measurement methods suffer from drawbacks: in situ sensors are expensive and difficult to maintain, while remote sensing offers lower accuracy and resolution. WaDAR bridges this gap by using inexpensive underground backscatter tags paired with above-ground radars, enabling completely wireless, high-resolution soil moisture monitoring.</p> <h2 id="key-features-of-wadar">Key Features of WaDAR</h2> <ul> <li>Uses <strong>RF backscatter tags</strong> buried underground to provide high-accuracy soil moisture readings.</li> <li>Uses <strong>ultra-wideband radar</strong> for above-ground sensing.</li> <li>Offers an average error of just 1.4%, comparable to state-of-the-art commercial sensors.</li> <li>Reduces deployment costs significantly, making it accessible for widespread agricultural use.</li> <li>Supports real-time, scalable, and maintenance-free soil moisture monitoring for farmers.</li> </ul> <h3 id="improving-and-optimizing-data-processing-pipeline-for-more-accurate-soil-moisture-measurements">Improving and Optimizing Data Processing Pipeline for More Accurate Soil Moisture Measurements</h3> <ul> <li><strong>Topics:</strong> <code>Digital Signal Processing</code> <code>Machine Learning</code></li> <li><strong>Skills:</strong> C/embedded, signal processing, machine learning, MATLAB (optional)</li> <li><strong>Difficulty:</strong> Moderate</li> <li><strong>Size:</strong> Medium (175 hours)</li> <li><strong>Mentors:</strong> <a href="https://deploy-preview-1007--ucsc-ospo.netlify.app/author/colleen-josephson/">Colleen Josephson</a>, <a href="https://deploy-preview-1007--ucsc-ospo.netlify.app/author/eric-vetha/">Eric Vetha</a></li> </ul> <p>Enhance the accuracy of soil moisture measurements by refining the data processing pipeline.</p> <p>Tasks:</p> <ul> <li>Develop and test algorithms for noise reduction and signal improvement.</li> <li>Implement advanced filtering and statistical techniques to improve measurement precision.</li> <li>Validate improvements using real-world field data.</li> <li>Translate algorithms into embedded to be implemented in real-time embedded hardware.</li> </ul> <h3 id="improving-backscatter-tag-pcb">Improving Backscatter Tag PCB</h3> <ul> <li><strong>Topics:</strong> <code>Hardware Design</code> <code>Signal Processing</code></li> <li><strong>Skills:</strong> PCB design, RF knowledge</li> <li><strong>Difficulty:</strong> Moderate</li> <li><strong>Size:</strong> Medium (175 hours)</li> <li><strong>Mentors:</strong> <a href="https://deploy-preview-1007--ucsc-ospo.netlify.app/author/colleen-josephson/">Colleen Josephson</a>, <a href="https://deploy-preview-1007--ucsc-ospo.netlify.app/author/eric-vetha/">Eric Vetha</a></li> </ul> <p>Enhance the performance of WaDAR&rsquo;s backscatter tags by optimizing PCB design for improved signal-to-noise ratio (SNR) and implementing a communication protocol for tag identification.</p> <p>Tasks:</p> <ul> <li>Redesign PCB for improved readings.</li> <li>Implement and test a communication protocol to distinguish between multiple tags.</li> <li>Evaluate hardware changes in real-world field conditions.</li> <li>Optimize power consumption and scalability for practical deployment.</li> </ul>