Manufacturer Part Number
TPS7B6925QDBVRQ1
Manufacturer
Texas Instruments
Introduction
The TPS7B6925QDBVRQ1 is a high-performance, low drop-out (LDO) linear voltage regulator optimized for power management in automotive and other voltage regulation applications.
Product Features and Performance
Stable with ceramic output capacitors
Low dropout voltage: 1.58V @ 100mA
Fixed output voltage: 2.5V
Output current up to 150mA
Low quiescent current: 25 µA
Power supply rejection ratio: 60dB at 100Hz
Over current, over temperature, short circuit, and under voltage lockout protections
Product Advantages
High reliability under automotive temperature ranges
Designed for low power consumption applications
Ensures stable operation with ceramic capacitors
Robust protection features enhance safety and durability
AEC-Q100 qualified for automotive applications
Key Technical Parameters
Voltage Input (Max): 40V
Voltage Output (Min/Fixed): 2.5V
Dropout Voltage (Max): 1.58V @ 100mA
Current Output: 150mA
Quiescent Current (Iq): 25 µA
PSRR: 60dB (100Hz)
Operating Temperature: -40°C ~ 150°C
Quality and Safety Features
Overcurrent and overtemperature protection
Short circuit protection
Under voltage lockout (UVLO)
Automotive grade reliability (AEC-Q100 qualified)
Compatibility
Compatible with various automotive applications requiring stable voltage
Optimized for use with ceramic output capacitors
Application Areas
Automotive electronics
Power management in embedded systems
Industrial controls
Consumer electronics requiring stable voltage supply
Product Lifecycle
Status: Active
Not nearing discontinuation, with availability for replacements and potential upgrades
Several Key Reasons to Choose This Product
High input voltage tolerance up to 40V suitable for automotive and industrial applications
Low dropout and quiescent current for energy-efficient operation
Robust protection features ensure reliability and prolonged lifespan
AEC-Q100 qualification meets strict automotive industry standards
Broad compatibility with ceramic capacitors reduces design complexity