Micron Technology Tariff Inquiry

MT29F16G16ADACAH4:C

MT29F16G16ADACAH4:C Description

The MT29F16G16ADACAH4:C is a 16Gb (1G x 16) parallel NAND flash memory device from Micron Technology, designed for high-performance embedded storage applications. Operating within a 2.7V to 3.6V supply range, it features a parallel interface for fast data transfer and is organized in a 16-bit wide configuration, making it ideal for systems requiring high-density, non-volatile storage. The device is housed in a 63VFBGA package, ensuring compact integration in space-constrained designs. Although marked as Obsolete, it remains a reliable choice for legacy systems due to its robust architecture and RoHS3 compliance.

MT29F16G16ADACAH4:C Features

• High-Capacity Storage: 16Gbit (1G x 16) organization for large data handling.
• Wide Voltage Range: Operates at 2.7V–3.6V, suitable for low-power and industrial applications.
• Parallel Interface: Enables high-speed data access compared to serial alternatives.
• Industrial-Grade Reliability: 0°C to 70°C operating temperature range ensures stability in varied environments.
• Surface-Mount Design: 63VFBGA package optimizes PCB space and thermal performance.
• Compliance: RoHS3 and REACH Unaffected, meeting environmental standards.

MT29F16G16ADACAH4:C Applications

This NAND flash is tailored for systems demanding high-density, non-volatile memory with fast read/write performance. Key applications include:

• Embedded Systems: Firmware storage in industrial controllers, networking equipment, and automotive modules.
• Legacy Electronics: Upgrades or replacements for older designs requiring parallel NAND flash.
• Data Logging: High-capacity storage for telemetry, medical devices, and IoT edge nodes.
• Consumer Electronics: Used in set-top boxes, printers, and gaming consoles where parallel interfaces are preferred.

Conclusion of MT29F16G16ADACAH4:C

The MT29F16G16ADACAH4:C offers a balance of high capacity, speed, and reliability, making it a strong candidate for legacy and embedded applications. While newer serial NAND solutions may dominate modern designs, this parallel flash remains relevant for systems requiring proven performance and compatibility. Its industrial-grade specs and compliance ensure longevity in demanding environments, though designers should consider its obsolete status for future-proofing.