ON Semiconductor MC100LVELT22DTR2 Dual Translator

The MC100LVELT22DTR2 is a versatile dual translator integrated circuit (IC) designed and manufactured by ON Semiconductor. This high-performance device is engineered to address the needs of signal translation between different logic levels within electronic systems. It is particularly suited for applications that demand high-speed operation and reliable performance in a wide range of industrial, telecommunications, and data communication environments.

The MC100LVELT22DTR2 belongs to the 100ELT family, which is known for its capability to translate any differential signal to a 3.3V LVPECL level with minimal skew and high bandwidth. This makes the IC an ideal choice for systems that require precise timing and synchronization.

Key Features

• Logic Level Translation: Capable of translating signals from differential inputs to 3.3V LVPECL outputs.
• High-Speed Performance: Designed for applications that demand fast signal processing with a maximum frequency exceeding 2.5 GHz.
• Low Skew: Provides excellent signal integrity with minimal pulse skew, ensuring reliable and consistent data transmission.
• Power Supply: Operates with a supply voltage of 3.3V ±10%, accommodating standard power supply levels in modern electronic equipment.
• Temperature Range: Functional across an extended industrial temperature range, making it suitable for harsh operating conditions.
• Packaging: Available in a TSSOP package, which is ideal for space-constrained applications due to its compact footprint.

Applications

• Data Communication Equipment
• Telecommunications Infrastructure
• High-Speed Data Acquisition Systems
• Signal Distribution and Translation
• Networking and Switching Equipment

The MC100LVELT22DTR2 is a testament to ON Semiconductor's commitment to providing high-quality, high-performance components for the electronics industry. With its robust design and advanced features, this dual translator is a reliable solution for designers looking to bridge different logic levels while maintaining signal fidelity and operational efficiency.