Following these 12 steps when designing gate drive transformers will ensure a long component life and optimal performanceSeguir leyendo
Autor: Bhuvana Madhaiyan
Bhuvana Madhaiyan is a Design and Development Engineer with Talema India. She holds a bachelor’s degree in Electrical and Electronics Engineering from Anna University Chennai and has been a practicing engineer since 2006. Bhuvana joined the Talema team in 2007.
Gate Drivers, Power Supply, SMPS, Switched-Mode
8 cosas que hay que considerar antes de diseñar un transformador de Gate Drive
Several important factors need to be considered when designing an optimized gate drive transformer (GDT). This article discusses several GDT design considerations, as well as ideal applications for their use. Two of the critical components to control when designing a gate-drive transformer are the leakage inductance and distributed capacitance. High leakage inductance and distributed capacitance...Seguir leyendo
Gate Drivers, Power Supply, SMPS, Switched-Mode
Gate Drive Transformer Pulse Response Characteristics
A gate drive transformer must reproduce the shape of an input pulse as accurately as possible at its secondary terminals. The performance of a gate drive transformer’s pulse characteristics is specified in terms of its effect on the shape of the pulse input current/voltage. It is important that the transformer must reproduce the shape of...Seguir leyendo
Gate Drivers, SMPS, Switched-Mode
Gate Drive Transformers and Circuits
A gate drive transformer is optimized for transmitting rectangular electrical pulses with fast rise and fall times to activate or deactivate a switching device. Despite various floating channel MOSFET/IGBT driver ICs being available, a transformer-coupled gate drive is still the better option to use for high power applications for many reasons. For example, due to the multiple...Seguir leyendo
Gate Drivers, Power Supply, SMPS, Switched-Mode
Introduction to Gate Drivers for Power Electronics
A gate driver is a power amplifier that accepts a low-power input from a controller IC and produces the appropriate high current gate drive for a power device. As requirements for power electronics continue to increase, the design and performance of the gate driver circuitry are becoming ever more important.Seguir leyendo
Power Supply, SMPS, Switched-Mode
12 pasos para diseñar transformadores SMPS
Designing magnetic components for SMPS can be challenging due to the increasing demands of modern electronics designs. Following these 12 steps can help engineers navigate the challenges and ensure a successful projectSeguir leyendo
Power Supply, SMPS, Switched-Mode
SMPS: Phase-Shifted Full-Bridge Converters
Phase-shifted full-bridge (PSFB) converters reduce switching loss and increase efficiency by phase-shifting the gate signals between the leading leg and the lagging leg switches without additional circuitsSeguir leyendo
Power Supply, SMPS, Switched-Mode
SMPS: Resonant Converters
Demand for smaller electronics (and thus smaller power supplies) continues to increase. Resonant techniques are used to allow for high-frequency operation in switched-mode power supplies, which in turn allows for smaller componentsSeguir leyendo
Power Supply, SMPS, Switched-Mode
SMPS: Symmetrical Isolated Converters
The fourth article in our series on switched-mode power supplies (SMPS) covers the main types of symmetrical isolated converter topologies: push-pull, half-bridge, y full-bridgeSeguir leyendo
Power Supply, SMPS, Switched-Mode
SMPS: Asymmetrical Isolated Converters
Isolated SMPS topologies are split into two main categories depending upon how the transformer is utilized: asymmetrical and symmetrical. In this article, we discuss asymmetrical isolated converter topologies.Seguir leyendo
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