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MT48H8M16LFB4-6:K TR
Product Overview
Category
The MT48H8M16LFB4-6:K TR belongs to the category of dynamic random access memory (DRAM) chips.
Use
This product is primarily used in computer systems, servers, and other electronic devices that require high-speed data storage and retrieval.
Characteristics
- High-speed operation: The MT48H8M16LFB4-6:K TR offers fast data transfer rates, making it suitable for applications that demand quick access to large amounts of data.
- Large storage capacity: With a capacity of 8 megabits (1 megabyte), this DRAM chip can store a significant amount of information.
- Low power consumption: The chip is designed to operate efficiently, consuming minimal power during its operation.
- Compact package: The MT48H8M16LFB4-6:K TR comes in a small form factor package, allowing for easy integration into various electronic devices.
- RoHS compliant: This product adheres to the Restriction of Hazardous Substances directive, ensuring its environmental friendliness.
Packaging/Quantity
The MT48H8M16LFB4-6:K TR is typically packaged in tape and reel format, providing ease of handling during manufacturing processes. It is available in quantities suitable for both small-scale and large-scale production.
Specifications
- Memory Type: Dynamic Random Access Memory (DRAM)
- Organization: 8 Megabits x 16 bits
- Operating Voltage: 3.3V
- Speed Grade: 6
- Package Type: FBGA (Fine-Pitch Ball Grid Array)
- Temperature Range: -40°C to +85°C
Detailed Pin Configuration
The MT48H8M16LFB4-6:K TR features a fine-pitch ball grid array (FBGA) package with a total of 54 pins. The pin configuration is as follows:
- VDD
- DQ0
- DQ1
- DQ2
- DQ3
- DQ4
- DQ5
- DQ6
- DQ7
- VSS
- DQ8
- DQ9
- DQ10
- DQ11
- DQ12
- DQ13
- DQ14
- DQ15
- VSS
- A0
- A1
- A2
- A3
- A4
- A5
- A6
- A7
- VSS
- A8
- A9
- A10
- A11
- A12
- A13
- A14
- A15
- VSS
- BA0
- BA1
- RAS#
- CAS#
- WE#
- CKE
- CS#
- VSS
- CLK
- DQM0
- DQM1
- VSS
- DM0
- DM1
- VCC
- VCC
- VSS
Functional Features
The MT48H8M16LFB4-6:K TR offers the following functional features:
- Random Access: The chip allows for random access to any memory location, enabling efficient data retrieval.
- Burst Mode: It supports burst mode operation, allowing for consecutive data transfers without the need for repeated address input.
- Auto Refresh: The DRAM chip automatically performs periodic refresh cycles to maintain data integrity.
- Self-Refresh: It has a self-refresh mode that reduces power consumption when the chip is idle.
Advantages and Disadvantages
Advantages
- High-speed operation enables quick data access.
- Large storage capacity accommodates substantial amounts of information.
- Low power consumption contributes to energy efficiency.
- Compact package facilitates integration into various electronic devices.
- RoHS compliance ensures environmental friendliness.
Disadvantages
- Requires periodic refresh cycles, which can temporarily interrupt data access.
- Sensitive to electrical noise and requires proper signal conditioning for optimal performance.
Working Principles
The MT48H8M16LFB4-6:K TR operates based on the principles of dynamic random access memory. It stores data in capacitors within its memory cells, which need to be periodically refreshed to maintain the stored information. When a read or write operation is initiated, the chip accesses the specific memory location using the provided address and transfers the data accordingly.
Detailed Application Field Plans
The MT48H8M16LFB4-6:K TR finds applications in various fields, including:
1.
Enumere 10 preguntas y respuestas comunes relacionadas con la aplicación de MT48H8M16LFB4-6:K TR en soluciones técnicas
1. What is the MT48H8M16LFB4-6:K TR?
The MT48H8M16LFB4-6:K TR is a specific model of synchronous dynamic random-access memory (SDRAM) chip.
2. What is the purpose of the MT48H8M16LFB4-6:K TR in technical solutions?
The MT48H8M16LFB4-6:K TR is commonly used as a primary memory component in various electronic devices and systems, such as computers, servers, networking equipment, and embedded systems.
3. What are the key features of the MT48H8M16LFB4-6:K TR?
Some key features of the MT48H8M16LFB4-6:K TR include a capacity of 128 megabytes (MB), a data transfer rate of 6 gigabits per second (Gbps), and a low operating voltage of 1.35 volts.
4. What is the pin configuration of the MT48H8M16LFB4-6:K TR?
The MT48H8M16LFB4-6:K TR has a 60-ball VFBGA (Very Fine Pitch Ball Grid Array) package with a specific pin configuration. Please refer to the datasheet or technical documentation for the exact pinout details.
5. What is the recommended operating temperature range for the MT48H8M16LFB4-6:K TR?
The recommended operating temperature range for the MT48H8M16LFB4-6:K TR is typically between -40°C to +85°C.
6. Can the MT48H8M16LFB4-6:K TR be used in both commercial and industrial applications?
Yes, the MT48H8M16LFB4-6:K TR is designed to be used in both commercial and industrial applications, thanks to its wide operating temperature range and robust performance.
7. What is the power consumption of the MT48H8M16LFB4-6:K TR?
The power consumption of the MT48H8M16LFB4-6:K TR depends on various factors such as operating frequency, voltage, and the specific usage scenario. Please refer to the datasheet for detailed power consumption specifications.
8. Is the MT48H8M16LFB4-6:K TR compatible with other memory modules or systems?
Yes, the MT48H8M16LFB4-6:K TR follows industry-standard protocols and interfaces, making it compatible with a wide range of memory controllers and systems that support SDRAM technology.
9. Can the MT48H8M16LFB4-6:K TR be used for high-performance computing applications?
Yes, the MT48H8M16LFB4-6:K TR can be used in high-performance computing applications that require fast and reliable memory access, thanks to its high data transfer rate and low latency characteristics.
10. Are there any specific design considerations when using the MT48H8M16LFB4-6:K TR in technical solutions?
When designing with the MT48H8M16LFB4-6:K TR, it is important to consider factors such as signal integrity, power supply stability, and proper timing constraints to ensure optimal performance and reliability. It is recommended to consult the datasheet and application notes provided by the manufacturer for detailed design guidelines.