Review on Control Strategy for Improving The Interleaved Converter Performances

“…For the first stage, a Dual Active Bridge (DAB) isolated converter was chosen: this topology assures bidirectionality and a fairly wide output voltages range and ZVS region, along with simplicity in the control [13,15]. The second stage is realized by means of a multi-way synchronous Buck converter with interleaved control, which allows improved control bandwidth [22,23] and a fine regulation of the output characteristics due to a higher equivalent switching frequency of the interleaved regime. Alongside boosting the control bandwidth, the interleaved-induced equivalent-frequency step-up enables magnetic and capacitors form-factors reduction in the filter, without increasing semiconductor switching losses, thus permitting a higher volumetric power density of the system.…”

Design of a 350 kW DC/DC Converter in 1200-V SiC Module Technology for Automotive Component Testing

“…For the first stage, a Dual Active Bridge (DAB) isolated converter was chosen: this topology assures bidirectionality and a fairly wide output voltages range and ZVS region, along with simplicity in the control [13,15]. The second stage is realized by means of a multi-way synchronous Buck converter with interleaved control, which allows improved control bandwidth [22,23] and a fine regulation of the output characteristics due to a higher equivalent switching frequency of the interleaved regime. Alongside boosting the control bandwidth, the interleaved-induced equivalent-frequency step-up enables magnetic and capacitors form-factors reduction in the filter, without increasing semiconductor switching losses, thus permitting a higher volumetric power density of the system.…”

Design of a 350 kW DC/DC Converter in 1200-V SiC Module Technology for Automotive Component Testing

Interleaving Technique for Improving Conventional Buck Converter Performance

Voltage-Mode Fuzzy Logic Controller for Enhancing Synchronous Buck Converter Operation