STMicroelectronics HCF4016M013TR Overview

The HCF4016M013TR from STMicroelectronics is a high-performance monolithic quad bilateral switch integrated circuit, designed for the transmission or multiplexing of analog or digital signals. It is part of the CMOS family and is renowned for its low power consumption and wide voltage range capabilities.

This versatile IC is housed in an SOIC-14 package, ensuring a compact footprint suitable for space-constrained applications. The device operates over a wide supply voltage range from 3V to 20V, providing flexibility for various design requirements. The low "ON" resistance of the switch is another key feature, which significantly reduces signal attenuation and ensures reliable signal transmission.

The HCF4016M013TR is characterized by its high degree of linearity and very low quiescent power dissipation, which is essentially independent of the supply voltage. These attributes make it a perfect choice for battery-operated devices. The bilateral switches of this IC are capable of handling both analog and digital signals, and the signal range extends from the negative supply voltage to the positive supply voltage.

This product is widely used in various applications including signal gating, chopper, modulator, demodulator and CMOS logic implementation. Its robust design also allows for the implementation in communication systems, instrumentation, and process control where reliable switch operation is critical.

The HCF4016M013TR is designed for medium-speed operation, ensuring compatibility with a broad range of devices and systems. It is also built to be highly reliable, with a latch-up performance that meets 100mA per JESD 78, Class II level A. This makes it a safe and dependable choice for critical applications.

In summary, the HCF4016M013TR from STMicroelectronics is a versatile, low-power quad bilateral switch IC that is ideal for a multitude of analog and digital applications. Its wide voltage range, low power dissipation, and robust design make it a valuable component in any electronic system design.