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As of my last update in September 2021, DCAP3 is a relatively new concept to combine the advantages of switched-capacitor converters and traditional inductor-based converters. I can provide you with a general outline of the steps to design a DCAP3 Converter:
Familiarize yourself with the DCAP3
Topology
Define your Requirements
Select Components
Design Control Circuitry
Model and Simulate
Prototype and Test
Optimize Efficiency
To design a DCAP3 power converter, you need to follow these steps:
Decide on the Control Scheme, such as feed forward voltage mode , emulated current mode , and DCAP3
Choose a power supply IC, considering the input/output voltages and current requirements
Your XC6241B2819R-G Ultra-LowSupply Current Voltage Regulator has a 6V max input, 5V max output,150mA current output
Define the switching frequency. For DCAP3, the frequency is estimated
Your XC6241B2819R-G Ultra-LowSupply Current has a 1kHZ frequency with high ripple rejection,which is not recommended for this application
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