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Saraswat Akshaya Pati

New Delhi, IN

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About

Motivated and detail-oriented Electrical and Electronics Engineering graduate with a strong foundation in system modeling, analysis, and industrial measurement techniques. Through academic coursework, hands-on projects, and laboratory experience, I have developed solid technical knowledge and analytical problem-solving skills to effectively address engineering challenges. Currently pursuing a Master’s degree in Electrical Engineering with a specialization in Control Systems and Instrumentation, aiming to deepen my expertise and gain practical exposure in advanced control methodologies and instrumentation technologies. Committed to continuous learning and contributing to innovative engineering solutions in a dynamic professional environment.

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Experience

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Education

  • Delhi Technological University
    Master of Technology · Control and Instrumentation
    20242026 · 6.9 (Till 3rd semester)
  • Vellore Institute of Technology
    Bachelor of Technology · Electrical and Electronics Engineering
    20202024 · 6.96
  • Narayana e-Techno School
    Higher Secondary · Science
    20192020 · 8.44
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  • Narayana e-Techno School
    Secondary
    20172018 · 8.1

Skills

  • MATLAB/Simulink

  • Python Basics

  • Arduino

  • IoT

  • Sensor Interfacing

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  • Control System

  • Power Electronics

  • Electrical Machines

Projects

  • RL-Assisted control of Rotary Inverted Pendulum (Ongoing)

    A MATLAB/Simulink model of a rotary inverted pendulum has being developed to analyze the nonlinear dynamics and stability characteristics of the system. A nonlinear control framework is being designed to enhance stabilization performance and improve dynamic response under varying initial conditions. Ongoing work focuses on integrating reinforcement learning concepts to adapt control parameters and further improve system robustness and transient behavior

    MATLAB/Simulink
  • Object Detection and Obstacle Alert System using YOLO Algorithm

    A real-time object detection and obstacle alert system was developed by integrating ultrasonic sensors and a camera module with an Arduino-based microcontroller platform. The system utilizes the YOLO (You Only Look Once) algorithm for efficient visual object detection, combined with ultrasonic sensing for distance measurement. A sensor fusion approach was implemented to improve detection reliability and reduce false alerts. The system triggers a buzzer when obstacles are detected within a predefined range, demonstrating practical application in automation, safety systems, and intelligent monitoring.

    ArduinoPython (basics)IoT
  • IoT-Based Smart Energy Meter

    Designed and implemented a real-time electrical parameter monitoring system using voltage and current sensors interfaced with a microcontroller. Developed cloud-based remote monitoring through Blynk platform to track power consumption, enabling load analysis and anomaly detection. The project demonstrates practical implementation of real-time energy monitoring, load tracking, and remote supervision concepts applicable to modern electrical systems.

    ArduinoIoT
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  • IoT based control of Interleaved Boost Converter

    An interleaved boost converter was designed and simulated in MATLAB/Simulink to analyze its operating behavior and performance characteristics. Basic Arduino-based switching control was applied within the simulation framework to observe voltage regulation and current sharing between interleaved phases. The interleaved configuration demonstrated reduced input current ripple and improved output voltage ripple performance compared to a single-phase boost converter in simulation.

    MATLAB/SimulinkArduinoIoT
  • Intelligent DC-DC Bidirectional Converter

    A bidirectional DC-DC converter was designed and simulated in MATLAB/Simulink to analyze controlled power flow in buck and boost operating modes. A digital control strategy was implemented and tuned within the simulation environment to improve the transient response and steady-state behavior of the converter. The simulation results demonstrated a 32% reduction in settling time and 45% reduction in steady-state error in boost mode, along with a 28% reduction in settling time and 15% reduction in steady-state error in buck mode.

    MATLAB/Simulink