Key Responsibilities: Design and develop high-power WPT coils specifically for EV wireless charging applications. Conduct coil-to-coil testing to evaluate and optimize transfer efficiency under various operating conditions. Design and implement compensation networks to support high-efficiency resonant power transfer. Analyze and design coil shielding systems to reduce electromagnetic interference (EMI) and ensure compliance with safety standards. Perform thermal analysis of coils to ensure system reliability and thermal stability. Collaborate with power electronics engineers, mechanical designers, and embedded system developers for integrated product development. Document all designs, test results, and technical specifications in a clear and organized manner. Required Skills and Qualifications: PHD or Master’s degree in Electrical Engineering, Electronics, or a related field. Proven experience in WPT coil design for high-power applications (EVs preferred). Strong understanding of magnetic field theory , resonant circuits , and power transfer principles . Hands-on experience with coil design tools, simulation software (e.g., ANSYS Maxwell, COMSOL, MATLAB), and thermal analysis. Familiarity with testing methodologies and instrumentation for WPT systems. Strong problem-solving skills, attention to detail, and ability to work independently and in a team environment. Preferred Qualifications: Experience working in the EV wireless charging domain.(2-3 years) Knowledge of relevant standards (e.g., SAE J2954, IEC standards) for wireless EV charging. Phd or masters degree. Show more Show less
Responsibilities: Assist in the design and development of mobile applications using Flutter. Contribute to building and maintaining web applications using React.js. Write clean, maintainable, and efficient code. Collaborate with the team to design UI/UX components and implement responsive interfaces. Debug, test, and fix issues to improve application performance. Learn and apply best practices in version control (Git), API integration, and state management. Participate in code reviews and brainstorming sessions to enhance project outcomes. Requirements: Basic knowledge of Flutter/Dart for mobile app development. Familiarity with React.js, JavaScript/TypeScript, HTML, CSS for web development. Understanding of REST APIs and integration methods. Knowledge of state management libraries (e.g., Provider, Redux, Context API) is a plus. Strong problem-solving skills and eagerness to learn. Ability to work independently as well as in a collaborative team environment. Currently pursuing or recently completed a degree in Computer Science, IT, or related field. Good to Have (Bonus Skills): Experience with Firebase, Node.js, or backend APIs. Familiarity with responsive design frameworks (Tailwind, Bootstrap, Material UI). Knowledge of deployment (Play Store, App Store, Vercel, Netlify).
We are seeking a motivated Power Electronics Intern with a strong academic background in electrical/electronics engineering to join our hardware design team. The role offers hands-on exposure to converter topologies, power semiconductor devices, magnetics, control techniques, simulations, PCB design, and real-world hardware testing. This is an excellent opportunity for candidates aspiring to build a career in power electronics R&D, hardware design, and system development. Key Responsibilities Assist in the design, simulation, and testing of power electronic converters (DC-DC, DC-AC, AC-DC, AC-AC). Perform circuit simulations using SPICE tools (LTspice, PSpice, Simplis), MATLAB/Simulink, PSIM, or Plecs. Support magnetics design for high-frequency transformers and inductors, including EMI considerations. Work on gate driver circuits , isolation techniques, and thermal management. Participate in PCB design for high-voltage/high-current applications with a focus on safety, creepage, and clearance. Conduct lab measurements using oscilloscopes, differential probes, power analyzers, and thermal cameras. Assist in debugging switching waveforms, measuring efficiency, and EMI/EMC compliance . Collaborate with senior engineers to document findings and propose design improvements. Required Knowledge & Skills Strong fundamentals of Power Electronics and converter topologies: DC-DC: Buck, Boost, Flyback, Forward, Resonant DC-AC: PWM inverters, Multilevel inverters, SPWM, SVPWM AC-DC: Single-phase & three-phase rectifiers, Active PFC AC-AC: Cycloconverters, Matrix converters Understanding of power semiconductor devices : MOSFETs, IGBTs, SiC & GaN devices, gate drivers, isolation, and thermal considerations. Basics of analog and digital control : stability analysis, Bode plots, MCU/DSP/FPGA-based implementations. Familiarity with magnetics design : core selection, winding, and EMI reduction. Exposure to PCB design practices for high-voltage/high-current systems. Hands-on experience with lab instruments for power electronics testing. Knowledge of safety practices when handling >100 V / >50 A systems. Qualifications Pursuing or recently completed PhD / M.Tech / M.S. in Electrical, Electronics, or related field . Coursework or project experience in power converters, inverter design, or motor drives . Strong analytical and problem-solving skills with a passion for hardware design.
We are seeking a motivated Power Electronics Intern with a strong academic background in electrical/electronics engineering to join our hardware design team. The role offers hands-on exposure to converter topologies, power semiconductor devices, magnetics, control techniques, simulations, PCB design, and real-world hardware testing. This is an excellent opportunity for candidates aspiring to build a career in power electronics R&D, hardware design, and system development. Key Responsibilities Assist in the design, simulation, and testing of power electronic converters (DC-DC, DC-AC, AC-DC, AC-AC). Perform circuit simulations using SPICE tools (LTspice, PSpice, Simplis), MATLAB/Simulink, PSIM, or Plecs. Support magnetics design for high-frequency transformers and inductors, including EMI considerations. Work on gate driver circuits, isolation techniques, and thermal management. Participate in PCB design for high-voltage/high-current applications with a focus on safety, creepage, and clearance. Conduct lab measurements using oscilloscopes, differential probes, power analyzers, and thermal cameras. Assist in debugging switching waveforms, measuring efficiency, and EMI/EMC compliance. Collaborate with senior engineers to document findings and propose design improvements. Required Knowledge & Skills Strong fundamentals of Power Electronics and converter topologies: DC-DC: Buck, Boost, Flyback, Forward, Resonant DC-AC: PWM inverters, Multilevel inverters, SPWM, SVPWM AC-DC: Single-phase & three-phase rectifiers, Active PFC AC-AC: Cycloconverters, Matrix converters Understanding of power semiconductor devices: MOSFETs, IGBTs, SiC & GaN devices, gate drivers, isolation, and thermal considerations. Basics of analog and digital control: stability analysis, Bode plots, MCU/DSP/FPGA-based implementations. Familiarity with magnetics design: core selection, winding, and EMI reduction. Exposure to PCB design practices for high-voltage/high-current systems. Hands-on experience with lab instruments for power electronics testing. Knowledge of safety practices when handling >100 V / >50 A systems. Qualifications Pursuing or recently completed PhD / M.Tech / M.S. in Electrical, Electronics, or related field. Coursework or project experience in power converters, inverter design, or motor drives. Strong analytical and problem-solving skills with a passion for hardware design.
Job Summary We are seeking a highly skilled PCB Engineer with 45 years of hands on experience in PCB layout, signal and power integrity, EMI/EMC compliance, thermal analysis, and high current/high voltage board design. The ideal candidate will work closely with hardware, and mechanical teams to develop reliable, manufacturable, and high performance PCB for complex systems. Key Responsibilities Create multilayer PCB layouts using industry standard EDA tools. Define and optimize PCB stack ups, ensuring controlled impedance, signal integrity, and power integrity. Perform differential pair routing, length matching, and impedance matching for high-speed signals. Design for manufacturability (DFM), testability (DFT), and assembly (DFA), working with PCB fabricators and assembly partners to ensure production feasibility. Apply EMI/EMC best practices during layout, including grounding, shielding, return paths, filtering, decoupling, and copper pour strategies. Perform thermal modeling and analysis (via thermal vias, copper pours, heat sinks, etc.) to ensure effective heat dissipation. Identify potential thermal hotspots and propose mitigation strategies (thermal vias, heatsinks, component placement). Design power electronics PCBs handling high current and/or high-voltage tracks, considering isolation, creepage/clearance, and safety standards. Perform signal integrity (SI) and power integrity (PI) simulations or analysis using tools such as HyperLynx, Sigrity, SIwave, or equivalent. Identify and mitigate issues like crosstalk, reflections, ground bounce, and power supply noise. Create and maintain component footprint libraries, 3D models, and design rule check (DRC) templates. Work closely with electrical engineers, firmware engineers, mechanical teams, and test/validation teams to integrate PCBs into the overall product.