Srinivasa Reddy

Highly motivated and results-driven 17+ years experienced wireless testing professional with a strong background in testing and optimizing wireless communication systems. Possesses a deep understanding of wireless technologies like Wi-Fi, Wi-Fi Direct, Bluetooth Low Energy, low power IoT applications, Zephyr RTOS deployments. Debugging complex wireless systems and end-to-end automation for CI/CD deployments.

Currently learning and creating simulation programs for Quantum Computing using different Quantum Computing frameworks like Qiskit, Cirq, Q#, Pennylane, Braket etc

Worked on different wireless technology standards and protocols testing related to 802.16e WiMAX, 802.11a/b/g/n/ac/ax/be Wi-Fi technologies, 11ax/be features like Multi RU allocation, DL and UL OFDMA, Power Save mechanisms, Long Range performance, Radio Frequency (RF) characteristics of Wi-Fi signals, Wi-Fi performance and throughput measurements

Created end-to-end Python based automation for CI/CD of Wi-Fi and IoT related projects utilizing GitHub Actions Workflows as well as Jenkins based systems.

Worked with Zephyr RTOS for lower power IoT projects to test different features using

Experience with Juniper routers (MX-80, 240, 480, 960), Litepoint equipment

In-depth knowledge on routing and switching protocols like vlans, OSPF, static routing

Proficient with Python, MicroPython scripting and test tools

Ability to build end to end IoT applications over BLE, Wi-Fi technologies

Ability to understand the technical requirements for testing and planning the test and automation strategy

Ability to perform Root Cause Analysis (RCA) of any Wi-Fi and Bluetooth related failures and customers reported issues

Quantum Computing Projects and Research Highlights

Developed bidirectional communication between two physical devices using pyzmq and quantum encryption prototypes.

Experimented with hybrid classical-quantum secure channel concept using frequency encoding and random key generation.

2. Quantum-Inspired Energy Simulation

Implemented frequency-to-symbol mapping akin to qubit state transitions to model non-classical interactions.

3. Quantum Algorithm Simulation

Visualized amplitude evolution and qubit entanglement states using Bloch sphere tools.

4. Quantum Key Distribution (QKD) Prototype

Integrated channel simulation using pyzmq for multi-device experiments.

Publications / Research Interests

Exploring cross-domain integration of quantum field theory, human energy modeling, and computational resonance systems.

Master of Science in Electrical Engineering – Halmstad University, Sweden