Tag Archives: hard
5 Professional Virus Removal Techniques
Virus removal can be tricky for the average computer owner. This is because, depending on the virus you catch, sometimes functions and applications that can be run are limited. In some instances the virus is so bad that the Ctrl + Alt + Delete function cant even be done. Professionals use several different, more complex techniques for virus removal on your desktop or laptop. These techniques are above the level of running anti-virus software and clicking a few different buttons to get the job done and are the biggest reasons people turn to professionals when those simple techniques just dont cut it.
Reconnecting Hard Drive
One technique professionals use is to disconnect the hard drive from the infected computer and reconnect it to a computer that has the latest anti-virus software installed on it. This is good for the computer that has been infected and not protected by anti-virus software. The hard drive is cleaned up by the clean computer. All too often, computers come to professionals that have caught a virus and have absolutely no protection whatsoever by anti-virus software, making it necessary to completely disconnect an infected hard drive and reconnecting it to one that is protected.
Safe Mode
Booting the computer into safe mode will, with some viruses, give the specialist a little bit more wiggle room to get in there and remove the virus themselves without having to resort to more drastic options like disconnecting the hard drive. In safe mode, milder viruses are kept at bay until the worker can maneuver and clear away the virus. Safe mode can also keep your computer safe from additional viruses until the first ones can be taken care of.
Reinstall Hard Drive
Sometimes with medium-toughness viruses, reinstalling the hard drive can give the computer a chance to kind of regroup and fight harder to allow the professional to manually remove viruses from it. Reinstalling the hard drive is one of those “drastic measures” listed above, because its much more difficult than running anti-virus software like with smaller virus pests.
System Restore
In cases where the virus hasnt completely limited the amount of options we can use to remove viruses, a system restore can be achieved. System restores can completely wipe out the hard drive, causing you to lose everything, or they can restore your computer to a date previous to when the problems started, back to a time when the virus wasnt there. System restores can be very effective, but professionals are best to carry them out to prevent any more data loss than necessary.
Advanced Anti-Virus
Anti-virus software that you buy in a store and install on your computer is often quite simple and works best for simple, less complex viruses. Hard-hitting, debilitating viruses, however, sometimes require more advanced and complex anti-virus software. Software like this is most often used by professionals and allows them to get a more firm hold on the virus (especially those tough ones) an eliminate them more thoroughly.
The Truth about RAID Technology
RAID – Redundant Array of Inexpensive (or sometimes “Independent”) Disks – is a method of combining several hard drives into one logical unit. It can offer fault tolerance and higher throughput levels than a single hard drive or group of independent hard drives.
RAID is a mature technology that speeds up data access while at the same time protecting your data from hard disk failure. RAID is quickly becoming a necessary component in every network since data loss and downtime can prove both fatal and financially destructive. Most networks are designed to provide instant access to massive amounts of data. More and more employees have to access customer and other databases. Intranets and corporate Web sites provide access to huge databases online.
RAID provides increased storage capacities, and protects your important data from hard drive failure.
RAID Levels:
RAID 0
RAID 1
RAID 3
RAID 5
RAID 10
There are multiple benefits of using RAID:
Reliability
Scalability
Real-time data recovery with uninterrupted access when a hard drive fails
System uptime and network availability
Protection against data loss
multiple drives working in parallel increase system performance
A disk system with RAID capability can protect its data and provide on-line, immediate access to its data, despite a single disk failure (some RAID storage systems can withstand two concurrent disk failures). RAID capability also provides for the on-line reconstruction of the contents of a failed disk to a replacement disk.
RAID offers faster hard drive performance and nearly complete data safety. Storage requirements are expanding as file sizes get bigger and rendering needs get more complex. If you handle very large images or work on audio and video files, faster data throughput means enhanced productivity. RAID can be backed up to tape while the system is in use.
There are 5 most commonly used RAID levels. These levels are not ratings, but rather classifications of functionality. Different RAID levels offer dramatic differences in performance, data availability and data integrity depending on the specific I/O environment. There is no single RAID level that is perfect for all users.
Storage Requirements can be calculated through RAID Calculator.
RAID 0: STRIPING
RAID 0 refers to striping data across multiple disks without any redundant information. Data is divided into blocks and distributed sequentially among the disks. This level is also referred to as pure striping. The number of disk drives needed to create a RAID 0 is one or more. In other words, a single drive can be configured as a RAID 0 array. This type of array can be used to enhance performance in either a request rate intensive or transfer rate intensive environment. Unfortunately, striping reduces the level of data availability since a disk failure will cause the entire array to be inaccessible.
RAID 0 was not defined originally but has become a commonly used term.
Advantages:
Easy to Implement
No capacity loss – all storage is usable
Disadvantages:
Not a “true” RAID due to the lack of fault-tolerance
Failure of only one disk will result in loss of all data on the array
RAID 1: MIRRORING / DUPLEXING
RAID 1 is the first defined level that allows a measure of data redundancy. Data written to one disk drive is simultaneously written to another disk drive. If one disk fails, the other disk can be used to run the system and reconstruct the failed disk. Since the disk is mirrored, it does not matter if one of them fails because both disks contain the same data at all times.
RAID level 1 provides high data availability since two complete copies of all information are maintained. In addition, read performance may be enhanced if the array controller allows simultaneous reads from both members of a mirrored pair. Higher availability will be achieved if both disks in a mirror pair are on separate I/O busses, known as duplexing.
Advantages:
Higher read performance than a single disk
Disadvantages:
Requires twice the desired disk space
RAID 3: SRTIPING AND PARITY
In RAID 3, data is striped across a set of disks. In addition, parity is generated and stored on a dedicated disk. With RAID 3, data chunks are much smaller than the average I/O size and the disk spindles are synchronized to enhance throughput in transfer rate intensive environments. RAID 3 is well suited for CAD/CAM or imaging type applications as well as streaming media. Since parity is used, a RAID 3 stripe set can withstand a single disk failure without losing data or access to data.
Advantages:
Good data availability
High performance for transfer rate intensive applications
Cost effective – only 1 extra disk is required for parity
Disadvantages:
Poor random I/O performance
Disk failure has a significant impact on performance
RAID 5: SRTIPING AND PARITY
RAID 5, similar to level 3, stripes data and parity to generate redundancy. However, instead of requiring entirely new disk for parity storage, the parity is distributed through the stripe of the disk array.
In RAID 5 both parity and data are striped across a set of separate disks. Next, the new parity is calculated. Finally, the new data and parity are written to separate disks. Data chunks are much larger than the average I/O size, but are still resizable. Disks are able to satisfy requests independently which provides high read performance in a request rate intensive environment. Since parity information is used, a RAID 5 stripe can withstand a single disk failure without losing data or access to data.
Advantages:
Highest read data transaction rates
Cost effective – only 1 extra disk is required
Disadvantages:
Individual block data transfer rate same as a single disk.
RAID 10
RAID 10 is technically (RAID 1 + RAID 0), a combination of RAID 1 and 0 – mirroring and striping, but without parity. RAID 10 is a stripe across a number of mirrored drives. It is implemented as a striped array whose segments are RAID 1 arrays. RAID 10 has the same fault tolerance as RAID level 1, as well as the same overhead for fault-tolerance as mirroring alone.
Advantages:
Very high I/O rates are achieved by striping RAID 1 segments
Excellent solution for sites that would normally use RAID 1
Great for Oracle and other databases which need high performance and fault tolerance.
Disadvantages:
Expensive to maintain
As with Raid 1 total capacity is equal to half of the total capacity of all disk in the array.
The Truth about RAID Technology
RAID – Redundant Array of Inexpensive (or sometimes “Independent”) Disks – is a method of combining several hard drives into one logical unit. It can offer fault tolerance and higher throughput levels than a single hard drive or group of independent hard drives.
RAID is a mature technology that speeds up data access while at the same time protecting your data from hard disk failure. RAID is quickly becoming a necessary component in every network since data loss and downtime can prove both fatal and financially destructive. Most networks are designed to provide instant access to massive amounts of data. More and more employees have to access customer and other databases. Intranets and corporate Web sites provide access to huge databases online.
RAID provides increased storage capacities, and protects your important data from hard drive failure.
RAID Levels:
RAID 0
RAID 1
RAID 3
RAID 5
RAID 10
There are multiple benefits of using RAID:
Reliability
Scalability
Real-time data recovery with uninterrupted access when a hard drive fails
System uptime and network availability
Protection against data loss
multiple drives working in parallel increase system performance
A disk system with RAID capability can protect its data and provide on-line, immediate access to its data, despite a single disk failure (some RAID storage systems can withstand two concurrent disk failures). RAID capability also provides for the on-line reconstruction of the contents of a failed disk to a replacement disk.
RAID offers faster hard drive performance and nearly complete data safety. Storage requirements are expanding as file sizes get bigger and rendering needs get more complex. If you handle very large images or work on audio and video files, faster data throughput means enhanced productivity. RAID can be backed up to tape while the system is in use.
There are 5 most commonly used RAID levels. These levels are not ratings, but rather classifications of functionality. Different RAID levels offer dramatic differences in performance, data availability and data integrity depending on the specific I/O environment. There is no single RAID level that is perfect for all users.
Storage Requirements can be calculated through RAID Calculator.
RAID 0: STRIPING
RAID 0 refers to striping data across multiple disks without any redundant information. Data is divided into blocks and distributed sequentially among the disks. This level is also referred to as pure striping. The number of disk drives needed to create a RAID 0 is one or more. In other words, a single drive can be configured as a RAID 0 array. This type of array can be used to enhance performance in either a request rate intensive or transfer rate intensive environment. Unfortunately, striping reduces the level of data availability since a disk failure will cause the entire array to be inaccessible.
RAID 0 was not defined originally but has become a commonly used term.
Advantages:
Easy to Implement
No capacity loss – all storage is usable
Disadvantages:
Not a “true” RAID due to the lack of fault-tolerance
Failure of only one disk will result in loss of all data on the array
RAID 1: MIRRORING / DUPLEXING
RAID 1 is the first defined level that allows a measure of data redundancy. Data written to one disk drive is simultaneously written to another disk drive. If one disk fails, the other disk can be used to run the system and reconstruct the failed disk. Since the disk is mirrored, it does not matter if one of them fails because both disks contain the same data at all times.
RAID level 1 provides high data availability since two complete copies of all information are maintained. In addition, read performance may be enhanced if the array controller allows simultaneous reads from both members of a mirrored pair. Higher availability will be achieved if both disks in a mirror pair are on separate I/O busses, known as duplexing.
Advantages:
Higher read performance than a single disk
Disadvantages:
Requires twice the desired disk space
RAID 3: SRTIPING AND PARITY
In RAID 3, data is striped across a set of disks. In addition, parity is generated and stored on a dedicated disk. With RAID 3, data chunks are much smaller than the average I/O size and the disk spindles are synchronized to enhance throughput in transfer rate intensive environments. RAID 3 is well suited for CAD/CAM or imaging type applications as well as streaming media. Since parity is used, a RAID 3 stripe set can withstand a single disk failure without losing data or access to data.
Advantages:
Good data availability
High performance for transfer rate intensive applications
Cost effective – only 1 extra disk is required for parity
Disadvantages:
Poor random I/O performance
Disk failure has a significant impact on performance
RAID 5: SRTIPING AND PARITY
RAID 5, similar to level 3, stripes data and parity to generate redundancy. However, instead of requiring entirely new disk for parity storage, the parity is distributed through the stripe of the disk array.
In RAID 5 both parity and data are striped across a set of separate disks. Next, the new parity is calculated. Finally, the new data and parity are written to separate disks. Data chunks are much larger than the average I/O size, but are still resizable. Disks are able to satisfy requests independently which provides high read performance in a request rate intensive environment. Since parity information is used, a RAID 5 stripe can withstand a single disk failure without losing data or access to data.
Advantages:
Highest read data transaction rates
Cost effective – only 1 extra disk is required
Disadvantages:
Individual block data transfer rate same as a single disk.
RAID 10
RAID 10 is technically (RAID 1 + RAID 0), a combination of RAID 1 and 0 – mirroring and striping, but without parity. RAID 10 is a stripe across a number of mirrored drives. It is implemented as a striped array whose segments are RAID 1 arrays. RAID 10 has the same fault tolerance as RAID level 1, as well as the same overhead for fault-tolerance as mirroring alone.
Advantages:
Very high I/O rates are achieved by striping RAID 1 segments
Excellent solution for sites that would normally use RAID 1
Great for Oracle and other databases which need high performance and fault tolerance.
Disadvantages:
Expensive to maintain
As with Raid 1 total capacity is equal to half of the total capacity of all disk in the array.