Manufacturer Part Number
TLC374IN
Manufacturer
Texas Instruments
Introduction
The TLC374IN is a quad differential comparator from Texas Instruments, designed utilizing the LinCMOS™ process.
Product Features and Performance
Quad differential inputs for flexible comparison
Compatible with CMOS, MOS, Open-Drain, and TTL outputs
Supports a wide range of supply voltages from 3V to 16V for single supply or ±1.5V to ±8V for dual supply
Low input offset voltage, maximum 5mV at 5V
Ultra-low input bias current, maximum 5pA at 5V
Capable of sourcing a 20mA output current typically
Quiescent current capped at 800µA for power efficiency
Product Advantages
High flexibility in interfacing with different logic types
Suitable for battery-powered applications due to low power consumption
Precision design enhances accuracy in signal comparison
Minimal input bias current, reducing errors in high impedance sensing circuits
Key Technical Parameters
Voltage Supply, Single/Dual (±): 3V ~ 16V, ±1.5V ~ 8V
Voltage Input Offset (Max): 5mV @ 5V
Current Input Bias (Max): 5pA @ 5V
Current Output (Typ): 20mA
Current Quiescent (Max): 800µA
Operating Temperature: -40°C ~ 85°C
Quality and Safety Features
Built in the robust LinCMOS™ process for enhanced stability and reliability
Operating temperature range ensures functionality in extreme conditions
Compatibility
Output compatible with CMOS, MOS, Open-Drain, TTL, making it versatile for a multitude of application circuits
Through-hole package (14-PDIP) for easy mounting on PCBs
Application Areas
Precision voltage monitoring
Signal conditioning
Battery management systems
Communication systems
Control systems
Product Lifecycle
Currently active, with no indication of impending discontinuation
Support for upgrades or replacements is available
Several Key Reasons to Choose This Product
High integration with four differential comparators in one package
Texas Instruments' reputation for quality and reliability
Low power operation suitable for energy-sensitive applications
Wide operating temperature range for diverse environments
Precision performance with low input offset and bias currents