What is Solid State Drive?

1. What is a solid state drive for? Solid State Drives offer faster storage and other performance advantages over fixed disks. Enterprises that are experiencing rapid growth in demand for higher input/output (I/O) are driving the development and adoption of SSDs. Because these drives provide lower latency than HDDs, they can efficiently handle heavy reads and random workloads. The lower latency stems from the ability of the flash SSD to read data directly from a particular flash SSD cell location. All-flash arrays only use SSDs as storage. Hybrid flash arrays combine disk storage and drives with flash memory for caching hot data that is later written to disk or tape. In a server-side flash configuration, solid state drives are installed on x86 computers to support target workloads, sometimes in conjunction with networked storage. High-performance servers, laptops, desktops, or any application that requires real-time or near real-time information can benefit from solid-state drive technology. These features make enterprise-class SSDs suitable for offloading reads from heavily transactional databases, mitigating boot storms using virtual desktop infrastructure (VDI), or inside storage arrays to store hot data locally in a hybrid cloud solution for offsite storage.

2. Solid state drives are used in a variety of consumer devices, including computer games, digital cameras, digital music players, laptops, personal computers, smart phones, tablets and thumb drives. These devices are not designed to provide the same performance or durability as enterprise-class SSDs. Main feature The design of the SSD has several features. Since it does not use moving parts, SSDs are not affected by mechanical failures that occur with HDDs. It is also quieter and consumes less power than its disks. And because SSDs weigh less than hard drives, they are ideal for laptops and mobile computing devices. In addition, the SSD controller software includes predictive analytics that alert users before a potential drive failure. Because flash memory is malleable, all-flash array vendors can manipulate available storage capacity through data reduction techniques. SSDs are typically built using single-level cells (SLC) or MLC flash. The SLC driver stores 1 bit of data per flash media unit. MLC-based SSDs double drive capacity by splitting the data into two parts. Newer SSDs (called TLCs) are on the market, with each flash cell storing 3 bits of data. TLC is cheaper than SLC or MLC, making it an attractive choice for consumer-based flash device manufacturers. TLC-based SSDs provide more flash capacity and are less expensive than MLC or SLC, although the likelihood of bit corruption is higher due to having eight states within the cell. SSD Shape Solid State Drives do not have physical limitations of Hard Disk Drive. This enables drive manufacturers to offer SSDs in a variety of shapes. The most common form factor is the 2.5- inch SSD, available in a variety of heights, including Serial Attached SCSI (SAS), Serial Advanced Technology Attachment (SATA) and Non-Volatile Memory Express (NVMe) protocols.

3. The Solid State Storage Program (SSSI) is a project of the Storage Networking Industry Association (SNIA) that has identified three major SSD shapes for the enterprise. The SSD factor in traditional hard drives is for the same SAS and SATA slots in the server. Solid state cards that use standard add-on card form factors, such as those that interconnect fast (PCIe) serial cards using peripheral components residing on a printed circuit board. PCIe-connected SSDs do not require a network host bus adapter (HBA) to relay commands, which speeds up storage performance. These devices, including U.2 SSDs, are often considered the ultimate replacement for miniSATA drives currently used in thin laptops. Solid-state modules, located in dual in-line memory modules (DIMMs) or small dual in-line memory modules (SO-DIMMs), can use standard HDD interfaces such as SATA. These devices are called non-volatile DIMM (NVDIMM) cards. Two types of random access memory (RAM) are used in computer systems: dynamic random access memory (DRAM), which loses data when power is lost, and static random access memory (SRAM). NVDIMMs provide the persistent storage required for computers to recover data. The NVDIMM places the flash memory close to the motherboard, but the operation is done in DRAM. The flash component is inserted into the memory bus for backup on high performance storage. Both SSD and RAM contain solid-state chips, but the two memory types have different functions in computer systems. As described above, a flash memory is a storage medium, and RAM is an active memory for performing calculation of data retrieved from storage. Read more…https://ddevices.com/online-store.php