TLV75201 Series
1-A, low-IQ, high-PSRR, adjustable, dual-channel low-dropout (LDO) voltage regulator
Manufacturer: Texas Instruments
Catalog(2 parts)
| Part | Package / Case | Output Type | PSRR▲▼ | PSRR▲▼ | Current - Output▲▼ | Voltage - Output (Max)▲▼ | Mounting Type | Voltage - Input (Max)▲▼ | Voltage Dropout (Max)▲▼ | Control Features | Supplier Device Package | Protection Features | Current - Quiescent (Iq)▲▼ | Output Configuration | Operating Temperature▲▼ | Operating Temperature▲▼ | Voltage - Output (Min/Fixed)▲▼ | Number of Regulators▲▼ |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Texas Instruments TLV75201PDSQTLinear Voltage Regulator IC Positive Adjustable 2 Output 1A 10-WSON (2x2) | 10-WFDFN Exposed Pad | Adjustable | 30 ul | 50 ul | 1 A | 5.5 V | Surface Mount | 6 V | 1.0499999523162842 V | Enable | 10-WSON (2x2) | Over Current, Over Temperature, Under Voltage Lockout (UVLO) | 0.000035000000934815034 A | Positive | 125 °C | -40 °C | 0.550000011920929 V | 2 ul |
Texas Instruments TLV75201PDSQRLinear Voltage Regulator IC Positive Adjustable 2 Output 1A 10-WSON (2x2) | 10-WFDFN Exposed Pad | Adjustable | 30 ul | 50 ul | 1 A | 5.5 V | Surface Mount | 6 V | 1.0499999523162842 V | Enable | 10-WSON (2x2) | Over Current, Over Temperature, Under Voltage Lockout (UVLO) | 0.000035000000934815034 A | Positive | 125 °C | -40 °C | 0.550000011920929 V | 2 ul |
Key Features
• Input voltage range: 1.5 V to 6.0 VAdjustable output voltage:0.55 V to 5.5 VVery low dropout:225 mV (max) at 1 A (3.3 VOUT)High output accuracy:1.5%, maximum over temperatureIQ: 25 µA (typical)Built-in soft-start with monotonic VOUTrisePackage:2-mm × 2-mm 10-Pin WSON (DSQ)Active output dischargeInput voltage range: 1.5 V to 6.0 VAdjustable output voltage:0.55 V to 5.5 VVery low dropout:225 mV (max) at 1 A (3.3 VOUT)High output accuracy:1.5%, maximum over temperatureIQ: 25 µA (typical)Built-in soft-start with monotonic VOUTrisePackage:2-mm × 2-mm 10-Pin WSON (DSQ)Active output discharge
Description
AI
The TLV752 is a dual, adjustable, 1-A low-dropout (LDO) regulator. This device is available in a small, 10-pin, 2-mm × 2-mm WSON package and consumes 25-µA quiescent current while providing fast line and load transient response. The TLV752 features a low dropout of 225 mV that can help improve the overall power efficiency.
The TLV752 wide input-and-output voltage ranges, when combined with its output current capability in a small printed circuit board (PCB) footprint help support a wide variety of applications from sensor supplies, to auxiliary rails, and modern microcontrollers with lower core voltages.
The TLV752 is stable with small ceramic output capacitors, allowing for a small overall solution size. A precision band-gap and error amplifier provides high accuracy of 1.5% (max) over temperature. This device includes integrated thermal shutdown, current limit, active output-discharge, and undervoltage lockout (UVLO) features. The TLV752 has an internal fold-back current-limit to reduce thermal dissipation during short-circuit events.
The TLV752 is a dual, adjustable, 1-A low-dropout (LDO) regulator. This device is available in a small, 10-pin, 2-mm × 2-mm WSON package and consumes 25-µA quiescent current while providing fast line and load transient response. The TLV752 features a low dropout of 225 mV that can help improve the overall power efficiency.
The TLV752 wide input-and-output voltage ranges, when combined with its output current capability in a small printed circuit board (PCB) footprint help support a wide variety of applications from sensor supplies, to auxiliary rails, and modern microcontrollers with lower core voltages.
The TLV752 is stable with small ceramic output capacitors, allowing for a small overall solution size. A precision band-gap and error amplifier provides high accuracy of 1.5% (max) over temperature. This device includes integrated thermal shutdown, current limit, active output-discharge, and undervoltage lockout (UVLO) features. The TLV752 has an internal fold-back current-limit to reduce thermal dissipation during short-circuit events.