ON Semiconductor MC10H604FNR2 Product Overview

The MC10H604FNR2 is a versatile and high-performance quadruple translator device designed and manufactured by ON Semiconductor, a leading name in the semiconductor industry. This device is part of the 10H series and is specifically engineered to translate signals from TTL to MECL levels, making it an essential component in a wide range of digital applications where interfacing between different logic levels is required.

Constructed with advanced ECLinPS technology, the MC10H604FNR2 delivers fast propagation delays and minimal rise and fall times, which are crucial for high-speed operations. The device features four non-inverting translator circuits that can handle data rates up to 1 GHz, thereby accommodating the needs of high-speed data communication and processing systems.

The MC10H604FNR2 comes in a compact 28-lead PLCC (Plastic Leaded Chip Carrier) package, which not only saves valuable board space but also offers robust protection for the internal circuitry. This packaging is suitable for surface mount technology (SMT), which allows for efficient assembly and integration into various electronic systems.

Key specifications of the MC10H604FNR2 include a wide operating voltage range and low power consumption, making it an energy-efficient choice for modern electronic designs. The device also features a differential PECL mode of operation, which provides improved noise immunity and signal integrity, especially in environments with high electrical noise.

ON Semiconductor's commitment to quality ensures that the MC10H604FNR2 meets stringent industry standards for reliability and performance. The device is commonly used in applications such as data transmission, telecommunications, and high-speed computing, where signal integrity and conversion between logic families are paramount.

In summary, the MC10H604FNR2 from ON Semiconductor is a high-speed quadruple translator that offers reliable TTL to MECL level translation with exceptional performance characteristics. Its compact form factor, low power consumption, and advanced technology make it an ideal choice for designers looking to bridge the gap between incompatible logic levels in their digital systems.