TIDT330
june
2023
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1
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Description
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Features
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Applications
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1Test Prerequisites
- 1.1
Voltage and Current Requirements
- 1.2
Considerations
- 1.3
Dimensions
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2Testing and Results
- 2.1
Efficiency Graphs
- 2.1.1
One Low-Side FET , 680-nH Coil , 1.0
VIN – 1.5 VIN
- 2.1.2
One Low-Side FET , 680-nH Coil , 2.0
VIN – 3.0 VIN
- 2.2
Load Regulation
- 2.2.1
One Low-Side FET, 680-nH Coil, 1.0
VIN – 1.5 VIN
- 2.2.2
One Low-Side FET, 680-nH Coil, 2.0
VIN – 3.0 VIN
- 2.3
Thermal Images
- 2.3.1
1.0-V Input Voltage – Full Load 3.0 A
- 2.3.1.1
Two Low-Side FETs, 330-nH Coil
- 2.3.1.2
One Low-Side FET, 680-nH Coil
- 2.3.2
2.0-V Input Voltage, Full Load 3.0
A
- 2.3.2.1
Two Low-Side FETs, 330-nH Coil
- 2.3.3
3.0-V Input Voltage, Full Load 3.0
A
- 2.3.3.1
Two Low-Side FETs, 330-nH Coil
- 2.4
Bode Plots
- 2.4.1
1.0-V Input Voltage
- 2.4.2
2.0-V Input Voltage
- 2.4.3
3.0-V Input Voltage
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3Waveforms
- 3.1
Switching Q2 FET (Drain to Source)
- 3.1.1
1.0-V Input Voltage
- 3.1.2
3.0-V Input Voltage
- 3.2
Output Voltage Ripple
- 3.2.1
1.0-V Input Voltage
- 3.2.2
3.0-V Input Voltage
- 3.3
Input Voltage Ripple
- 3.3.1
1.0-V Input Voltage
- 3.3.2
3.0-V Input Voltage
- 3.4
Load Transients
- 3.4.1
Load Steps of 1.5 A to 3 A
- 3.4.1.1
1.0-V Input Voltage
- 3.4.1.2
3.0-V Input Voltage
- 3.4.2
Load Steps of 0.2 A to 3 A
- 3.4.2.1
1.0-V Input Voltage
- 3.4.2.2
3.0-V Input Voltage
- 3.5
Start-Up Sequence
- 3.5.1
1.0-V Input Voltage
- 3.5.2
3.0-V Input Voltage
- 3.6
Shutdown Sequence
- 3.6.1
1.0-V Input Voltage
- 3.6.2
3.0-V Input Voltage
Features
- Converter can operate from a single-cell
supercapacitor and deliver 24 W of output power
- Operates down to 1.0-V input voltage
enabling deep discharge of a supercapacitor
- High-efficiency conversion due to use of
synchronous rectification
- Starts up from as low as 1.25 V
- Design has been built and tested