RAID stands for Redundant Array of Inexpensive/Independent Disks. RAID is a technique of data virtualization that uses multiple hard disks or solid-state drives to provide for data redundancy and performance improvement. Redundancy provides threat resilience to the data in case of unforeseen events, thus proving advantageous over the conventional storage technique of having a “single large expensive disk” (SLED). So instead of having all the data on one SLED, RAID instead makes use of multiple small-sized disks allowing faster I/O operations and providing robustness to the whole system. In case one of the disks in the system crashes the others remain safe and the whole system doesn’t collapse.
RAID was first discussed by David Patterson, Randy Katz, and Garth A. Gibson in their technical report, “A Case for Redundant Arrays of Inexpensive Disks (RAID)” in the year 1988. The report discussed and established how RAI could be more resilient and reliable than a single disk.
- Data Redundancy: Data is stored in multiple disks and copies of same data are kept in different locations(disks) for disaster management.
- Use of multiple disks: Instead of using a single large disk, RAID stores data in many small less expensive disks.
- Use of multiple storage techniques:Different RAID levels use different storage techniques like-: striping, mirroring an parity to provide multiple features to the users.
- Multiple Systems:There are 6 different RAID levels and each provies some unique features and and compromises on some. It is up to the user and his requirements as to what can be use in their system.
- Data access speed: Data access speed in RAID systems is uneniably better that SLED systems. RAID 0, RAID 4 and RAID 5 are specially designed for fast and cheap data access.
- Reundant data: Data redundancy provided by RAID systems provides for a reliable storage system. RAID 1 uses data mirroring to keep copies of data to ensure reliability.
- Error Correction:RAID 2, RAID 3, RAID 4 and RAID 5 use hamming code parity for error correction in data.
- Simultaneous I/O requests: RAID 0, RAID 4 and RAID 5 use the striping storage techniques hence support multiple I/O operations at the same time.
- Bulk data transfer:RAID 3 provides for quick bulk data transfers.
- Data security:Striping and continuous parity checks privide for high data security.
- Cost: The cost of RAID systems is more than SLED systems.
- Data loss: The RAID systems that do not use mirroring are vulnerable to some data loss.
- Choice of RAID level:Given that there are so many RAID levels with each having some drawbacks and features of their it is a difficult choice as to what system can be used.
- Improper use:If RAID is not use properly, the overall performance of the system as a whole may decrease.
- Complex technology:RAID is a difficult to use architecture of data storage and requies skilled and proficient people to unlock the full potential of RAID.
- Difference between RAID 3 and RAID 4
- Difference between RAID 2 and RAID 3
- Difference between RAID 1 and RAID 2
- TCL Full Form
- LFU Full Form
- OSI Model Full Form in Computer Networking
- HDMi Full Form
- LCD Full Form
- RTC Full Form
- VLAN Full Form
- WPA Full Form
- SGML Full Form
- DHCP Full Form
- LED Full Form
- PIN Full Form
- MPEG Full Form
- GUI Full Form
- VRAM Full Form
- DDoS Full Form
- PATA full form
If you like GeeksforGeeks and would like to contribute, you can also write an article using contribute.geeksforgeeks.org or mail your article to email@example.com. See your article appearing on the GeeksforGeeks main page and help other Geeks.
Please Improve this article if you find anything incorrect by clicking on the "Improve Article" button below.