The 93LC86C-I/ST is a high-quality EEPROM (Electrically Erasable Programmable Read-Only Memory) device from the reputable Microchip Technology. This memory chip offers a robust storage solution for applications that require data retention without power. It is particularly well-suited for device configuration, calibration data storage, and any application where reliable and non-volatile memory is critical.

Key Features

• Memory Size: The 93LC86C-I/ST provides users with 16K (2048 x 8 or 1024 x 16) bits of memory, allowing for flexible data storage options.
• Operating Voltage: This device operates within a voltage range of 2.5V to 5.5V, making it versatile for various low-power applications.
• Temperature Range: With an industrial temperature range of -40°C to +85°C, the EEPROM can reliably function in harsh environments.
• Package: It comes in a surface-mount ST package, which is suitable for automated assembly processes and space-constrained applications.
• Communication: The chip employs a simple serial interface for communication, supporting both the Microwire and the SPI protocols, which ensures compatibility with a vast range of microcontrollers and processors.
• Write Cycle Time: It has a maximum write cycle time of 5 ms, enabling quick data updates and minimizing downtime for write operations.
• Endurance: The device boasts an endurance of 1,000,000 write cycles, ensuring a long operational lifespan for the memory.
• Data Retention: Data retention is rated at over 200 years, providing peace of mind for applications where data integrity over extended periods is paramount.

Applications

The 93LC86C-I/ST EEPROM from Microchip Technology is ideal for a wide array of applications, including but not limited to:

• Consumer Electronics
• Industrial Control Systems
• Medical Devices
• Automotive Systems
• Smart Cards

In summary, the 93LC86C-I/ST EEPROM offers a reliable, durable, and flexible non-volatile memory solution, perfect for a multitude of electronic applications where data integrity and device reliability are crucial.