Manufacturer Part Number
TLV3494AID
Manufacturer
Texas Instruments
Introduction
Linear comparator with quadruple elements and CMOS push-pull outputs
Product Features and Performance
Four independent comparator channels
Rail-to-rail output
Low voltage operation starting from 1.8V
High precision with a maximum input offset voltage of 15mV at 5.5V
Extremely low input bias current, maximum 10pA at 5.5V
Ultra-low current consumption of 1.2µA max
Good common-mode rejection ratio of 74dB
PSRR of 69.12dB ensures stability against power supply variations
Maximum propagation delay of 13.5µs
Product Advantages
Optimized for battery-powered devices due to low power requirements
Suitable for voltage monitoring due to precision characteristics
Space-saving 14-SOIC package suitable for compact designs
Wide operating temperature range from -40°C to 125°C for use in various environments
Key Technical Parameters
Single/Dual Supply Voltage: 1.8V to 5.5V
Input Offset Voltage Max: 15mV
Input Bias Current Max: 10pA
Quiescent Current Max: 1.2μA
CMRR: 74dB
PSRR: 69.12dB
Propagation Delay Max: 13.5µs
Number of Elements: 4
Output Type: CMOS, Push-Pull, Rail-to-Rail
Quality and Safety Features
Extended temperature range ensures reliability in harsh conditions
Compatibility
Compatible with other CMOS and TTL logic systems
Application Areas
Battery monitoring
Power supply control
Signal level detection
Multivibrator circuits
Product Lifecycle
Active status indicates currently in production and not nearing discontinuation
Replacements or upgrades may be available upon inquiry
Several Key Reasons to Choose This Product
Low power consumption suitable for portable devices
Quadruple comparator design allows multiple comparisons in one package
CMOS push-pull output offers strong drive capability with rail-to-rail performance
Operational in a wide range of supply voltages, offering design flexibility
Robust design operates efficiently in extreme temperatures
High input impedance minimizes disturbances in the monitored signal
Comprehensive technical parameters fulfill demanding precision requirements