RAID 3 is a Redundant Array of Independent Disks (RAID) standard that utilizations striping at the byte level and stores committed equality bits on a different circle drive. Like RAID 2, RAID 3 requires an uncommon regulator that takes into account the synchronized turning, everything being equal. Rather than striping information blocks into various circles, RAID 3 stripes the pieces, which are put away on various plate drives. This setup is utilized less regularly than other RAID levels.

Explains RAID 3.

Since RAID 3 consolidates equality and striping with put away equality bits on a devoted plate, this setup needs somewhere around three separate hard circles – two for striping information and one for putting away equality bits. The plates should turn in a state of harmony, so consecutive read/compose (R/W) activities accomplish great execution. In any case, irregular R/W activities might make weighty efforts in execution.

In real terms, read speed is a lot more prominent than compose speeds in view of required checksum computations, which is a presentation bottleneck for the whole circle cluster.

RAID 3 benefits include: 

High throughput for moving a lot of information

Impervious to plate disappointment and breakdown, which prompts RAID 3’s primary disservices (beneath).

Inconveniences:

The arrangement might be excessively if a little document move is the main necessity.

Plate disappointments may essentially diminish throughput.

RAID 3 is a RAID setup that utilizes an equality circle to store the data produced by a RAID regulator as opposed to striping it with the information.

Since the equality data is on a different circle, RAID 3 doesn’t perform well when entrusted with various little information demands. RAID 3 is a superior decision for applications that have long consecutive information moves, like real time media, illustrations and video altering.