quality Consumer Grade RAM SSD & Industrial Grade Storage Memory manufacturer

DRAM Many people know what RAM is, but do you really know the different types of RAM and how they work? Wondering what DRAM stands for and why it’s important for your computer? Well, keep reading. “DRAM” stands for “dynamic random-access memory” and it’s a specific type of RAM (random access memory). By understanding what it is and how it works, you can make sure your system runs as smoothly as possible. Let’s dive in! What is DRAM? DRAM stands for dynamic random-access memory. It is a type of random access memory (RAM) that all computers have. DRAM is often used in PCs, laptops, smartphones and tablets, and many other types of computing devices. In simple terms, it provides temporary storage for files that are used when the computer is running programs or applications. What does DRAM do? All types of RAM, including DRAM, are volatile memories that store bits of data in transistors. This memory is also located closer to your processor, so your computer can access it easily and quickly for any processes you perform. It's like an invisible hard drive that temporarily stores data when you launch programs or switch between tasks on your machine. Why is DRAM important? DRAM is essential because it allows your computer to run efficiently by providing fast access to the essential data your processor needs to perform optimally. Without DRAM, your processor would have to scan through much slower storage media, such as hard drives or solid-state drives, every time it needed data. This would slow down operations considerably. Additionally, having enough RAM ensures that the programs you run don't weigh down your system because they remain in cache until they are no longer needed. Advantages of DRAM Here are some of the most notable benefits of DRAM: Fast Speed: One of the main advantages of DRAM is that it offers higher speeds than other types of RAM. This means that your computer will be able to process data much faster than if you were using a slower type of RAM. This speed advantage makes it ideal for applications such as gaming, video editing and 3D rendering, where speed is essential. Higher density : Density is high, meaning that more bits can be stored in less space than with other types of RAM. This allows for smaller devices, as less physical space is required to store the same amount of data as with SRAM or ROM. So it's an interesting option for mobile devices like smartphones and tablets, which require small form factors but need enough memory to run. Affordable : DRAM is relatively inexpensive compared to other forms of RAM, helping to reduce overall costs for consumers when purchasing new equipment or upgrading an existing system. The low cost also allows device manufacturers to include larger amounts of memory without significantly increasing the price of their products. Low Power Consumption: Another great advantage of DRAM is its low power consumption, as it requires fewer transistors than other forms of RAM like SRAM or ROM. Types of DRAM: There are several types of DRAM available today. The most common are: SDR (Single Data Rate), DDR (Double Data Rate), DDR2 (Double Data Rate 2), DDR3 (Double Data Rate 3), and DDR4 (Double Data Rate 4 ): These are the most common types of DRAM. They all have advantages and disadvantages depending on how much space they take up, how fast they process data, and how much power they consume. SDR is the oldest type of DRAM and is no longer very popular because it does not support high-speed data transfer rates. DDR is much faster than SDR, but it consumes more power. It is still widely used in many electronic devices such as computers, laptops, tablets, mobile phones, etc. DDR2 is twice as fast as DDR but consumes more power than its predecessor. DDR3 has higher speeds than DDR2 and DDR but consumes less power than its predecessors. Finally, DDR4 has higher speeds than all previous versions of DRAM but also consumes less power than them. 2. Synchronous DRAM or SDRAM: This type of DRAM works with a clock signal that synchronizes it with the rest of the system components in order to process data at a higher speed than asynchronous DRAM can achieve without a clock signal. It supports high transfer rates, making it ideal for applications such as video gaming that require real-time responses from system components to ensure that every action taken by players results in an immediate response from the system itself. ECC DRAM: This type of DRAM stands for Error Correction Code, meaning it checks for errors during data transfers to ensure that no data is corrupted or lost during transmission between two components of a system or when sending/receiving information from external sources such as hard drives or USB devices. It is therefore ideal for critical applications where any form of data corruption can lead to serious problems due to lack of accuracy or integrity when processing large amounts of information over long periods of time. DRAM Speeds DRAM speeds are measured in MHz (megahertz), with higher numbers indicating faster speeds. Generally speaking, the faster your RAM, the faster your computer will be able to read and write data from its main memory. This means that if you have faster RAM, you can access data faster and with less delay (i.e. latency). For example, if two computers have the same processor, but one has twice as much RAM and runs at twice the speed of the other, it is likely that its performance will be significantly better than its slower

What is DDR? DDR is a form of SDRAM that stands for Double Data Rate Synchronous Dynamic Random Access Memory. Don't worry, you do not have to remember all that! SDRAM synchronizes data transfer between the CPU and memory of your PC system. In 2000, DDR memory was released, and by 2014 the fourth iteration of DDR memory was launched (DDR4). Each iteration of DDR comes with performance improvements over its predecessor.   So, what is DDR5? DDR5 is the fifth iteration of DDR, doubling the bandwidth and capacity of its predecessor. Just like with new generations of processors and graphics cards increasing core/thread count and clock speeds, new memory generations come along to raise the ceiling, allowing applications to do even more things at once and typically resulting in more efficient computing.   DDR4 and DDR5 Key Differences Memory Bandwidth One of the main differences between DDR4 and DDR5 RAM is speed. The JEDEC spec of DDR4 operates at effective speeds of up to 3200MHz, up from its initial 2133MHz at launch, while DDR5 RAM can operate at effective speeds of up to 6400Mhz. And that is just the beginning, memory manufacturers are already talking about pushing the bandwidth even further, so don’t be surprised if you see DDR5 running at 8000MHz or more. You can find a broad variety of DDR4 RAM and DDR5 RAM on our main website.   Voltage On DDR4, power regulation and management are integrated into the motherboard for memory; on DDR5, each module has its own PMIC (Power Management Integrated Infinites). With this change, DDR5 memory ICs require less power, with Vdd dropping from 1.2v (DDR4) to 1.1v (DDR5), which translates to improved efficiency and power regulation, resulting in a higher ceiling when overclocking among other things. The downside is that despite its lower voltage DDR5 modules run warmer than a DDR4, so good heatsink & cooling technology is key to high performance.    Better voltage regulation Improved DRAM yields Reduced module power consumption compared to DDR Increased efficiency vs voltage regulation on the motherboard   Note: Memory support is governed by a combination of your motherboard and CPU. While your CPU may support both DDR4 and DDR5, your motherboard typically supports only one, either DDR4 or DDR5. This means you may need a new motherboard to take advantage of DDR5.    

A solid state drive is a storage device that uses solid state memory to store data. The principle behind solid state drives is that there should be no moving parts: no spinning platters, no moving heads. Data is split into word length pieces and stored in memory. It is then accessed almost instantaneously using unique system-wide addresses. Solid state disks use either NAND flash or SDRAM (non-volatile and volatile storage respectively). NAND flash is so-called because of the NAND-gate technology it uses and is common in USB flash drives and many types of memory card. NAND flash based drives are persistent and can therefore effectively mimic a hard disk drive. Synchronous dynamic random access memory (SDRAM) is volatile and requires a separate power source if it is to operate independently from a computer. Because the information on solid state drives can be accessed immediately (technically at the speed of light) there is no latency experience when data is transferred. Because there is no relationship between spatial locality and retrieval speed, there is no degradation of performance when data is fragmented. Mean time between failures (MTBF) There is a distinction between endurance and reliability. Reliability deals with how often SSDs or a disk drives fail. MTBF is the number of aggregate service hours, on average, a population of storage devices operate before a failure occurs on any one device. Fortunately, with modern server drive technology, MTBF is typically in the millions of hours. Reliability Because SSDs don’t have any moving part, they are nearly invulnerable to fail in high shock and vibration environments and extreme temperatures. This trait, particularly the potential of operating in extreme temperatures between 0°C to +70°C, allows an SSD-based system to handle more applications in difficult situations where the traditional hard drives fail. Performance consistency and service quality SSDs provide high performance which eventually improves the CPU Performance why lowering down the Disk/IO Wait Factor on the Server. More Disk/IO Wait, Less User Resource Available causing Deadlocks, Website Slow. Less Disk/IO Wait, More User Resource Available and Smooth Experience. PERFORMANCE An SSD has access speeds of 35 to 100 microseconds, which is nearly 500 times faster. RELIABILITY SSD uses flash memory to store data, which provides better performance and reliability over an HDD.   HYBRID CONFIGURATIONS SSDs can be configured as hybrid drives to act as a cache for the data stored on the server.   Superior Compatibly and Low Latency SSDs are compatible with any technology stack for your web applications.   SSDs are definitely the future of storage: they're getting more affordable and offer more storage space than ever before. The lastest generation of SSDs designed for datacentres are now just as reliable as mechanical HDDs, but offer up to 500 times more performance.