Rapidly explore different stackups, capacitor selections, placements, mounting schemes for their effect on design margins.Accurate modeling of plane structures for power delivery and noise propagation.Analyze power distribution impedance at power supply connections to critical ICs.Predict temperature rise with PI/thermal co-simulation.Decoupling capacitors provide local reservoirs of charge, but mounting inductances and proximity limit their Above ~1 MHz (AC), power plane and component pin inductances come into play, limiting how much current can be delivered at these frequencies. Cutouts and voids in power planes increase this effect. At low (DC) frequencies, resistive losses affect how much current can be supplied to components without excessive drop in supply voltage. Poorly designed PDNs can create current and thermal stresses that exceed physical material limits, causing the PCB or ICs to burn out prematurely. Provide controlled return paths for high-speed signals When a PDN fails to meet these goals, the design can fail to operate at intended performance levels, or even worse, fail intermittently and unpredictably.Supply stable power to components from DC to ~150 MHz.Identify areas of excessive current density in layout.Analyze voltage drop due to supply plane copper losses.Works with all major PCB layout and routing applications.Automated workflows with HyperLynx’s industry-renowned ease of use Overview Every modern electronic design includes a Power Distribution Network (PDN) with two critical and equally important.HyperLynx PI Power Delivery Network (PDN) Design Benefits
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