The Hynix H5TC8G43AMR-H9A is a high-performance DDR3 SDRAM (Synchronous Dynamic Random-Access Memory) chip designed for use in a wide range of applications, from consumer electronics to high-performance computing.

Applications:

• Desktop and laptop computers
• Servers
• Networking equipment
• Graphics cards
• Embedded systems

Features:

• 8Gb (1G x 8) memory organization
• Double Data Rate 3 (DDR3) technology
• Operating frequency up to 1600MHz
• Low power consumption
• 8-bit pre-fetch architecture
• On-Die Termination (ODT)
• Lead-free and Halogen-free
• RoHS compliant

Benefits:

• Increased memory bandwidth for faster data access
• Reduced power consumption for longer battery life in mobile devices
• Improved system performance due to higher operating frequency
• Enhanced reliability due to On-Die Termination
• Environmentally friendly due to lead-free and halogen-free construction

Additional Details:

The H5TC8G43AMR-H9A is a DDR3 SDRAM, meaning it transfers data on both the rising and falling edges of the clock signal, effectively doubling the data transfer rate compared to single data rate (SDR) SDRAM. The 8Gb density allows for larger memory capacity in systems, enabling the execution of more complex applications and handling larger datasets. The chip operates at a voltage of 1.5V, contributing to its low power consumption. The on-die termination feature improves signal integrity by reducing signal reflections, which leads to more reliable operation at high speeds. This DDR3 memory chip is often found in SODIMM and DIMM modules used in laptops, desktops, and servers.

The H5TC8G43AMR-H9A utilizes a 78-ball FBGA (Fine-Pitch Ball Grid Array) package for easy surface mounting onto printed circuit boards. It's designed to meet JEDEC standards, ensuring compatibility with other DDR3 components and systems. The specific speed grade, indicated by the '-H9A' suffix, defines the maximum operating frequency and timings. This component is designed for high-performance applications requiring fast memory access and efficient power management.