Your Capacitor Is Not Dying Quietly: SPICE Can Hear the Ripple First
SPICE-based ripple-current analysis gives power designers a practical way to see capacitor stress before heat, lifetime loss, and field failures show up in hardware.
SPICE-based ripple-current analysis gives power designers a practical way to see capacitor stress before heat, lifetime loss, and field failures show up in hardware.
High-current chip ferrite beads such as the MH3261-T series point to a denser EMI-suppression future for compact power designs.
High-current IHXL inductors rated up to 209 A with improved core losses show how magnetic components are adapting to denser, hotter power systems.
High-value, high-voltage thick-film resistors such as the SRT series show why precision stability still matters in demanding measurement, protection, and power designs.
Integrated voltage regulators are pulling thin-film magnetic power inductors into the package, changing how AI and GPU platforms think about power density, transient response, and board space.
Ripple current is a lifetime problem hiding inside power supplies, and SPICE-based FFT analysis gives engineers a practical way to estimate capacitor stress before heat wins.
AI servers are pushing high-end MLCC demand toward capacity limits, exposing how small passive components can become a serious constraint in the data-center hardware race.
AI accelerators are lifting silicon capacitors from a niche packaging detail into a premium supply-chain item tied to wafer capacity and long-term contracts.
A capacitive position-sensing approach using sensor-to-reference capacitance ratios highlights how simple analog building blocks can still deliver precise motion insight.
New high-current IHXL inductors with improved core losses point to rising power-density pressure in EV charging, industrial drives, PFC, and renewable-energy systems.