The TS393C from STMicroelectronics is a highly efficient, micro-power dual voltage comparator that boasts a wide range of features designed for applications requiring low power consumption and a wide single or dual supply voltage range. This product is an ideal choice for battery-powered devices and other applications where power efficiency is crucial.

Key Features

• Low Power Consumption: The TS393C is optimized for low power operation, making it suitable for portable and battery-operated applications where power efficiency is a priority.
• Wide Voltage Range: It operates from a single supply voltage ranging from 2.7V to 16V or a dual supply voltage from ±1.35V to ±8V, providing flexibility in various circuit designs.
• Dual Comparator: The device includes two independent voltage comparators that can be used in a variety of configurations, including zero-crossing detectors, window comparators, and oscillators.
• High Input Impedance: With a high input impedance, the TS393C ensures minimal input current, preserving the integrity of the signal and reducing power consumption.
• Output Compatibility: The output stage is designed to drive TTL or CMOS loads, making it compatible with a wide range of digital circuits.
• Extended Temperature Range: The operating temperature range of -40°C to +125°C allows the TS393C to be used in environments with extreme temperatures.

Applications

The versatility of the TS393C makes it suitable for a diverse set of applications, including:

• Portable and wearable devices
• Power supply control
• Automotive systems
• Alarm and security devices
• Analog-to-digital converters
• Timing circuits
• Industrial control systems

The TS393C is available in various packages, including the small outline package and the micro-package, allowing for efficient use of board space in compact electronic designs. With its robust design and comprehensive features, the TS393C from STMicroelectronics is a reliable and versatile choice for designers looking to enhance the performance of their low-power and voltage-sensitive applications.