ON Semiconductor MC10EP17DWR2G Product Overview

The MC10EP17DWR2G is a high-performance differential receiver from ON Semiconductor, designed to address the needs of high-speed data communication in modern electronic systems. This versatile component is part of ON Semiconductor's 10EP series, known for their reliability and efficiency in processing digital signals.

This differential receiver is capable of translating a PECL input signal to a CMOS output level, making it an ideal choice for interfacing between different signal domains. The MC10EP17DWR2G is characterized by its fast propagation delay and high data throughput, which are essential for applications requiring rapid signal processing and minimal latency.

The device comes in a compact SOIC-16 wide body package, which is conducive to space-constrained applications. It operates over a wide range of supply voltages from 3.0 V to 5.5 V, allowing for flexibility in various circuit designs. Additionally, the MC10EP17DWR2G boasts a temperature range of -40°C to +85°C, ensuring reliable performance in diverse operating conditions.

Key features of the MC10EP17DWR2G include a maximum frequency of 3.2 GHz, which provides the bandwidth necessary for high-speed data transmission. The receiver also has a low typical propagation delay of approximately 190 ps, contributing to its swift response times. Furthermore, its differential design helps to minimize common-mode noise, thus enhancing signal integrity in noisy environments.

Applications for the MC10EP17DWR2G are vast and include, but are not limited to, clock and data distribution, telecommunications, automated test equipment, and high-speed computing interfaces. Its robust design and high-speed capabilities make it a critical component for designers looking to optimize their high-speed digital systems.

In summary, the ON Semiconductor MC10EP17DWR2G differential receiver is a high-quality, versatile component that offers excellent performance for a wide range of high-speed data processing applications. Its integration into electronic systems helps ensure efficient and reliable communication between different signal domains, making it a valuable asset in the design of advanced electronic circuits.