Microchip Technology AT28C16E-15JC EEPROM

The AT28C16E-15JC is a high-performance, 16-Kilobit parallel EEPROM from Microchip Technology, designed to deliver a reliable storage solution for a wide range of applications. Engineered with precision, this EEPROM offers a 16,384 bits of memory, organized as 2,048 words by 8 bits each, making it ideal for storing configuration data, calibration settings, and various non-volatile data requirements.

This EEPROM operates at a speed of 150ns, ensuring swift data access and program execution. The AT28C16E-15JC comes in a robust 32-lead PLCC (Plastic Leaded Chip Carrier) package, providing excellent durability and ease of PCB mounting. Its compatibility with industry-standard microprocessors makes it a versatile choice for integration into numerous electronic systems.

Key features of the AT28C16E-15JC include:

• High-Density Storage: With its 16K memory, it offers ample space for critical data.
• Fast Access Time: The 150ns access time provides quick read operations, enhancing overall system performance.
• Low Power Consumption: It is designed for efficient power usage, making it suitable for battery-operated and power-sensitive applications.
• Write Protect Feature: This feature prevents accidental data overwrites and ensures data integrity.
• Easy Integration: The PLCC package and the compatibility with standard interfaces allow for seamless integration into existing designs.
• Wide Operating Range: It is designed to operate over a broad temperature range, ensuring reliability under varying environmental conditions.

The AT28C16E-15JC EEPROM is a testament to Microchip Technology's commitment to providing high-quality, reliable memory solutions. Whether used in industrial controls, automotive systems, medical devices, or consumer electronics, this EEPROM ensures data persistence and stability for critical applications. Its endurance and data retention capabilities make it a preferred choice for designers looking for a non-volatile memory component that can withstand the demands of rigorous and long-term usage.