“ARTIKEL”
Backup dan Recovery Data
Pengenalan:
Kehilangan data adalah hal yang sangat menakutkan, hal ini dapat terjadi kapan saja diluar perkiraanadministrator jaringan. Oleh karena itu banyak cara dan metode yang dilakukan untukmempertahankan dan memastikan ketersediaan data tersebut. Backup berarti duplikat atau copy-andari data yang diinginkan, duplikat dapat berupa physical (kertas) dan data2 komputer.Media kertas dapat membackup bukti pembayaran pajak, bukti2 finansial, surat kontrak kerja, dandokumen perusahaan penting lainnya. sedangkan media record data pada komputer selain dapatmenyimpan data2 yang dapat dibackup pada media kertas diatas juga dapat membackup e-mail, fileaudit, informasi user, utility and applikasi, sistem operasi, data dan database keuangan dan lainnya.Idealnya setiap data dari semua system dalam suatu perusahaan harus dibackup setiap hari secararegular dan dengan pengawasan khusus dari Backup Administrator.Merencanakan Backup dan Recoveryketika merencakan backup dan recovery data, ada beberapa hal yang harus dipertimbangkan untuk
membantu mengambil keputusan bagaimana, kapan, dan data mana yang akan dibackup, yaitu :1. Kapan sebaiknya backup dilakukan ?. Backup sebaiknya dilakukan diluar jam kerja pada saat trafik
jaringan kecil.2. Apakah media backup disimpan diluar kantor ?. Hal ini sangat efektif jika suatu saat terjadikebakaran dan bencana alam di kantor, sehingga kita masih dapat merestore data dr media backup
yang juga tersimpan diluar kantor.3. Seberapa penting data2 yang akan anda backup ?. Pelaksanaan dan ketentuan backup yangdilakukan terhadap data finansial akan lebih ketat dan berbeda dibandingkan backup untuk data2 userbiasa.
4. Seberapa cepat perubahan data?. Data yang berubah setiap hari akan dibackup setiap hari. Hal iniberhubungan dengan kapan backup dilakukan, harian, mingguan, bulanan, atau tahunan.
5. berapa ukuran data yang akan dibackup dan seberapa sering bencana kehilangan data pernahterjadi diperusahaan anda?. berhubungan dengna media backup yang akan digunakan.Selain pertanyaan diatas, mungkin ada ketentuan2 lain yang perlu dipertimbangkan tergantung padakondisi pada perusahaan masing2.
Jenis Backup
Full ( normal) : backup semua file yang dipilih tidak mempedulikan attibut archive bit file. Setelah filedibackup maka archive bit dari file tersebut akan dihapus sampai file tersebut dimodifikasi. Ketikaarchive bit diset kembali ini mengindikasikan bahwa data tsb telah berubah dan perlu dibackup lagi.Incremental : backup data yang mengalami perubahan sejak backup terakhir dilakukan. hanya file dgnarchive bit yang akan dibackup. archive bit akan dihapus setelah dilakukan incremental backup. Tipebackup ini menghemat penggunakan pita tapi memerlukan waktu yang lama untuk merestore datakarena data2 tersebar pada pita2 yang berbeda.Differential : Sama dengan tipe incremental tapi archive bit tidak dihapus setelah backup.Copy : sama dengan tipe full backup tapi archive bit tidak dihapus setelah file dibackup. jadi keadaanfile dibiarkan tetap seperti semula seperti sebelum dibackup.
Jenis Media Backup
1. Tape2. Disk Drive3. Removable Disk (Zip Disk)4. DAT (Digital audio Tape) drivesSama seperti tape biasa tp dgn kapasitas lebih besar. Beberapa format yg digunakan adalah DLT(Digital Linear Tape), SDLT (Super Digital Linear Tape), LTO (Linear Tape Open) dan AIT (AdvancedIntelligent Tape) , mampu membackup data hingga 260 GB.5. Optical JukeboxMenggunakan magnetic optical disk sebagai media penyimpanan, terkenal dalam kapasitaspenyimpanan hingga 20 TeraByte. Jukebox berupa tower yg secara otomatis dapat meloading internalstorage disk ketika diperlukan untuk backup atau restore data.6. Autoloader tape systemsmenggunakan kumpulan tape untuk membuat volume backup. Ia mempunyai kemampuan untukmeloading dan unloading otomatis tape dibutuhkan sehingga kita tidak perlu mengawasi prosesbackup karena tidak akan ada lagi prmp “l s i eta e2, l k rn i a tl d ro tp a e n rtp ′′o h ae a t uo a ee s e u omemerlukan aplikasi khusus unt menangani hal tersebut. Autoloader menggunakan DAT tape dgnformat DLT, LTO dan AIT. Dengan mengimplementasikan sebuah tape library system dgn multipledrive dapat diimprovisasi kecepatan proses backup hingga ratusan Gigabyte per jam.Beberapa faktor penting yang harus dipertimbangkan sebelum memutuskan media backup apa ygakan digunakan adalah : Kecepatan, Kapasitas, Tahan Lama dan Tangguh, serta biaya yang tersedia.











In information technology, a backup or the process of backing up refers to making copies of data so that these additional copies may be used to restore the original after a data loss event. The verb is back up in two words, whereas the noun is backup (often used like an adjective in compound nouns).[1]
Backups are useful primarily for two purposes. The first is to restore a state following a disaster (called disaster recovery). The second is to restore small numbers of files after they have been accidentally deleted or corrupted. Data loss is also very common. 66% of internet users have suffered from serious data loss.[2]
Since a backup system contains at least one copy of all data worth saving, the data storage requirements are considerable. Organizing this storage space and managing the backup process is a complicated undertaking. A data repository model can be used to provide structure to the storage. In the modern era of computing there are many different types of data storage devices that are useful for making backups. There are also many different ways in which these devices can be arranged to provide geographic redundancy, data security, and portability.
Before data is sent to its storage location, it is selected, extracted, and manipulated. Many different techniques have been developed to optimize the backup procedure. These include optimizations for dealing with open files and live data sources as well as compression, encryption, and de-duplication, among others. Many organizations and individuals try to have confidence that the process is working as expected and work to define measurements and validation techniques. It is also important to recognize the limitations and human factors involved in any backup scheme.
· Storage, the base of a backup system
Data repository models
Any backup strategy starts with a concept of a data repository. The backup data needs to be stored somehow and probably should be organized to a degree. It can be as simple as a sheet of paper with a list of all backup tapes and the dates they were written or a more sophisticated setup with a computerized index, catalog, or relational database. Different repository models have different advantages. This is closely related to choosing a backup rotation scheme.
Unstructured
An unstructured repository may simply be a stack of floppy disks or CD-R/DVD-R media with minimal information about what was backed up and when. This is the easiest to implement, but probably the least likely to achieve a high level of recoverability.
Full + Incrementals
A Full + Incremental repository aims to make storing several copies of the source data more feasible. At first, a full backup (of all files) is taken. After that, any number of incremental backups can be taken. There are many different types of incremental backups, but they all attempt to only backup a small amount of data relative to the full backup. Restoring a whole system to a certain point in time would require locating the full backup taken previous to that time and the incremental backups that cover the period of time between the full backup and the particular point in time to which the system is supposed to be restored.[3] The scope of an incremental backup is typically defined as a range of time relative to other full or incremental backups. Different implementations of backup systems frequently use specialized or conflicting definitions of these terms.
Differential backup
A differential backup copies files that have been created or changed since the last normal or incremental backup. It does not mark files as having been backed up (in other words, the archive attribute is not cleared). If you are performing a combination of normal and differential backups, restoring files and folders requires that you have the last normal as well as the last differential backup.
Reverse delta
A reverse delta system stores the differences between current versions of a system and previous versions. A reverse delta backup will start with a normal full backup. After the full backup is performed, the system will periodically synchronize the full backup with the live copy, while storing the data necessary to reconstruct older versions. This can either be done using hard links, or using binary diffs. This system works particularly well for large, slowly changing, data sets. Examples of programs that use this method are rdiff-backup and Time Machine
Continuous data protection
Instead of scheduling periodic backups, the system immediately logs every change on the host system. This is generally done by saving byte or block-level differences rather than file-level differences.[4] It differs from simple disk mirroring in that it enables a roll-back of the log and thus restoration of old image of data.
Full System backup
This type of backup is designed to allow an entire PC to be recovered to "bare metal" without any installation of operating system, application software and data. Most users understand that a backup will prevent "data" from being lost. The expense in a full system recovery is in the hours that it takes for a technician to rebuild a machine to the point of restoring the last data backup. This process is not understood[by whom?] and very few backup applications are able to achieve the result.
Storage media
Regardless of the repository model that is used, the data has to be stored on some data storage medium somewhere.
Magnetic tape
Magnetic tape has long been the most commonly used medium for bulk data storage, backup, archiving, and interchange. Tape has typically had an order of magnitude better capacity/price ratio when compared to hard disk, but recently the ratios for tape and hard disk have become a lot closer.[5] There are myriad formats, many of which are proprietary or specific to certain markets like mainframes or a particular brand of personal computer. Tape is a sequential access medium, so even though access times may be poor, the rate of continuously writing or reading data can actually be very fast. Some new tape drives are even faster than modern hard disks. A principal advantage of tape is that it has been used for this purpose for decades (much longer than any alternative) and its characteristics are well understood.
Hard disk
The capacity/price ratio of hard disk has been rapidly improving for many years. This is making it more competitive with magnetic tape as a bulk storage medium. The main advantages of hard disk storage are low access times, availability, capacity and ease of use.[6] External disks can be connected via local interfaces like SCSI, USB, FireWire, or eSATA, or via longer distance technologies like Ethernet, iSCSI, or Fibre Channel. Some disk-based backup systems, such as Virtual Tape Libraries, support data deduplication which can dramatically reduce the amount of disk storage capacity consumed by daily and weekly backup data. The main disadvantages of hard disk backups are that they are easily damaged, especially while being transported (e.g., for off-site backups), and that their stability over periods of years is a relative unknown.
Optical disc
A recordable CD can be used as a backup device. One advantage of CDs is that they can in theory be restored on any machine with a CD-ROM drive. (In practice, writable CD-ROMs are not always universally readable.) In addition, recordable CD's are relatively cheap. Another common format is recordable DVD. Many optical disk formats are WORM type, which makes them useful for archival purposes since the data can't be changed. Other rewritable formats can also be utilized such as CD-RW or DVD-RAM. The newer HD-DVDs and Blu-ray Discs dramatically increase the amount of data possible on a single optical storage disk, though, as yet, the media may be cost prohibitive for many people. Additionally the physical lifetime of the optical disk has become a concern as it is possible for some optical disks to degrade and lose data within a couple of years.[citation needed]
Floppy disk
During the 1980s and early 1990s, many personal/home computer users associated backup mostly with copying floppy disks. The low data capacity of a floppy disk makes it an unpopular and obsolete choice today.[7]
Solid state storage
Also known as flash memory, thumb drives, USB flash drives, CompactFlash, SmartMedia, Memory Stick, Secure Digital cards, etc., these devices are relatively costly for their low capacity, but offer excellent portability and ease-of-use.
Remote backup service
As broadband internet access becomes more widespread, remote backup services are gaining in popularity. Backing up via the internet to a remote location can protect against some worst-case scenarios such as fires, floods, or earthquakes which would destroy any backups in the immediate vicinity along with everything else. There are, however, a number of drawbacks to remote backup services. First, internet connections (particularly domestic broadband connections) are generally substantially slower than the speed of local data storage devices, which can be a problem for people who generate or modify large amounts of data. Secondly, users need to trust a third party service provider with both privacy and integrity of backed up data. The risk associated with putting control of personal or sensitive data in the hands of a third party can be managed by encrypting sensitive data so that its contents cannot be viewed without access to the secret key. Ultimately the backup service must itself be using one of the above methods, so this could be seen as a more complex way of doing traditional backups.
Managing the data repository
Regardless of the data repository model or data storage media used for backups, a balance needs to be struck between accessibility, security and cost. These media management methods are not mutually exclusive and are frequently combined to meet the needs of the situation. Using on-line disks for staging data before it is sent to a near-line tape library is a common example.
On-line
On-line backup storage is typically the most accessible type of data storage, which can begin restore in milliseconds time. A good example would be an internal hard disk or a disk array (maybe connected to SAN). This type of storage is very convenient and speedy, but is relatively expensive. On-line storage is quite vulnerable to being deleted or overwritten, either by accident, by intentional malevolent action, or in the wake of a data-deleting virus payload.
Near-line
Near-line storage is typically less accessible and less expensive than on-line storage, but still useful for backup data storage. A good example would be a tape library with restore times ranging from seconds to a few minutes. A mechanical device is usually involved in moving media units from storage into a drive where the data can be read or written. Generally it has safety properties similar to on-line storage.
Off-line
Off-line storage requires some direct human action in order to make access to the storage media physically possible. This action is typically inserting a tape into a tape drive or plugging in a cable that allows a device to be accessed. Because the data is not accessible via any computer except during limited periods in which it is written or read back, it is largely immune to a whole class of on-line backup failure modes. Access time will vary depending on whether the media is on-site or off-site.
Off-site data protection
To protect against a disaster or other site-specific problem, many people choose to send backup media to an off-site vault. The vault can be as simple as a system administrator’s home office or as sophisticated as a disaster hardened, temperature controlled, high security bunker that has facilities for backup media storage. Importantly a data replica can be off-site but also on-line (e.g., an off-site RAID mirror). Such a replica has fairly limited value as a backup, and should not be confused with an off-line backup.
Backup site or disaster recovery center (DR center)
In the event of a disaster, the data on backup media will not be sufficient to recover. Computer systems onto which the data can be restored and properly configured networks are necessary too. Some organizations have their own data recovery centers that are equipped for this scenario. Other organizations contract this out to a third-party recovery center. Because a DR site is itself a huge investment, backup is very rarely considered the preferred method of moving data to a DR site. A more typical way would be remote disk mirroring, which keeps the DR data as up-to-date as possible.
Selection and extraction of data
A successful backup job starts with selecting and extracting coherent units of data. Most data on modern computer systems is stored in discrete units, known as files. These files are organized into filesystems. Files that are actively being updated can be thought of as "live" and present a challenge to backup. It is also useful to save metadata that describes the computer or the filesystem being backed up.
Deciding what to backup at any given time is a harder process than it seems. By backing up too much redundant data, the data repository will fill up too quickly. Backing up an insufficient amount of data can eventually lead to the loss of critical information.
Files
Copying files
Making copies of files is the simplest and most common way to perform a backup. A means to perform this basic function is included in all backup software and all operating systems.
Partial file copying
Instead of copying whole files, one can limit the backup to only the blocks or bytes within a file that have changed in a given period of time. This technique can use substantially less storage space on the backup medium, but requires a high level of sophistication to reconstruct files in a restore situation. Some implementations require integration with the source filesystem.
Filesystems
Filesystem dump
Instead of copying files within a filesystem, a copy of the whole filesystem itself can be made. This is also known as a raw partition backup and is related to disk imaging. The process usually involves unmounting the filesystem and running a program like dump. This type of backup has the possibility of running faster than a backup that simply copies files. A feature of some dump software is the ability to restore specific files from the dump image.
Identification of changes
Some filesystems have an archive bit for each file that says it was recently changed. Some backup software looks at the date of the file and compares it with the last backup, to determine whether the file was changed.
Versioning file system
A versioning filesystem keeps track of all changes to a file and makes those changes accessible to the user. Generally this gives access to any previous version, all the way back to the file's creation time. An example of this is the Wayback versioning filesystem for Linux.[8]
Live data
If a computer system is in use while it is being backed up, the possibility of files being open for reading or writing is real. If a file is open, the contents on disk may not correctly represent what the owner of the file intends. This is especially true for database files of all kinds. The term fuzzy backup can be used to describe a backup of live data that looks like it ran correctly, but does not represent the state of the data at any single point in time. This is because the data being backed up changed in the period of time between when the backup started and when it finished. For databases in particular, fuzzy backups are worthless.
Snapshot backup
A snapshot is an instantaneous function of some storage systems that presents a copy of the filesystem as if it was frozen in a specific point in time, often by a copy-on-write mechanism. An effective way to backup live data is to temporarily quiesce it (e.g. close all files), take a snapshot, and then resume live operations. At this point the snapshot can be backed up through normal methods.[9] While a snapshot is very handy for viewing a filesystem as it was at a different point in time, it is hardly an effective backup mechanism by itself.
Open file backup
Many backup software packages feature the ability to handle open files in backup operations. Some simply check for openness and try again later. File locking is useful for regulating access to open files.
When attempting to understand the logistics of backing up open files, one must consider that the backup process could take several minutes to back up a large file such as a database. In order to back up a file that is in use, it is vital that the entire backup represent a single-moment snapshot of the file, rather than a simple copy of a read-through. This represents a challenge when backing up a file that is constantly changing. Either the database file must be locked to prevent changes, or a method must be implemented to ensure that the original snapshot is preserved long enough to be copied, all while changes are being preserved. Backing up a file while it is being changed, in a manner that causes the first part of the backup to represent data before changes occur to be combined with later parts of the backup after the change results in a corrupted file that is unusable, as most large files contain internal references between their various parts that must remain consistent throughout the file.
Cold database backup
During a cold backup, the database is closed or locked and not available to users. The datafiles do not change during the backup process so the database is in a consistent state when it is returned to normal operation.[10]
Hot database backup
Some database management systems offer a means to generate a backup image of the database while it is online and usable ("hot"). This usually includes an inconsistent image of the data files plus a log of changes made while the procedure is running. Upon a restore, the changes in the log files are reapplied to bring the database in sync.[11]
Metadata
Not all information stored on the computer is stored in files. Accurately recovering a complete system from scratch requires keeping track of this non-file data too.
System description
System specifications are needed to procure an exact replacement after a disaster.
Boot sector
The boot sector can sometimes be recreated more easily than saving it. Still, it usually isn't a normal file and the system won't boot without it.
Partition layout
The layout of the original disk, as well as partition tables and filesystem settings, is needed to properly recreate the original system.
File metadata
Each file's permissions, owner, group, ACLs, and any other metadata need to be backed up for a restore to properly recreate the original environment.
System metadata
Different operating systems have different ways of storing configuration information. Microsoft Windows keeps a registry of system information that is more difficult to restore than a typical file.
· Manipulation of data and dataset optimisation
It is frequently useful or required to manipulate the data being backed up to optimize the backup process. These manipulations provide many benefits including improved backup speed, restore speed, data security, media usage and reduced bandwidth requirements.
Compression
Various schemes can be employed to shrink the size of the source data to be stored so that it uses less storage space. Compression is frequently a built-in feature of tape drive hardware.
De-duplication
When multiple similar systems are backed up to the same destination storage device, there exists the potential for much redundancy within the backed up data. For example, if 20 Windows workstations were backed up to the same data repository, they might share a common set of system files. The data repository only needs to store one copy of those files to be able to restore any one of those workstations. This technique can be applied at the file level or even on raw blocks of data, potentially resulting in a massive reduction in required storage space. Deduplication can occur on a server before any data moves to backup media, sometimes referred to as source/client side deduplication. This approach also reduces bandwidth required to send backup data to its target media. The process can also occur at the target storage device, sometimes referred to as inline or back-end deduplication.
Duplication
Sometimes backup jobs are duplicated to a second set of storage media. This can be done to rearrange the backup images to optimize restore speed, to have a second copy at a different location or on a different storage medium.
Encryption
High capacity removable storage media such as backup tapes present a data security risk if they are lost or stolen.[12] Encrypting the data on these media can mitigate this problem, but presents new problems. Encryption is a CPU intensive process that can slow down backup speeds, and the security of the encrypted backups is only as effective as the security of the key management policy.
Multiplexing
When there are many more computers to be backed up than there are destination storage devices, the ability to use a single storage device with several simultaneous backups can be useful.
Refactoring
The process of rearranging the backup sets in a data repository is known as refactoring. For example, if a backup system uses a single tape each day to store the incremental backups for all the protected computers, restoring one of the computers could potentially require many tapes. Refactoring could be used to consolidate all the backups for a single computer onto a single tape. This is especially useful for backup systems that do incrementals forever style backups.
Staging
Sometimes backup jobs are copied to a staging disk before being copied to tape. This process is sometimes referred to as D2D2T, an acronym for Disk to Disk to Tape. This can be useful if there is a problem matching the speed of the final destination device with the source device as is frequently faced in network-based backup systems. It can also serve as a centralized location for applying other data manipulation techniques.
· Managing the backup process
It is important to understand that backup is a process. As long as new data is being created and changes are being made, backups will need to be updated. Individuals and organizations with anything from one computer to thousands (or even millions) of computer systems all have requirements for protecting data. While the scale is different, the objectives and limitations are essentially the same. Likewise, those who perform backups need to know to what extent they were successful, regardless of scale.
Objectives
Recovery point objective (RPO)
The point in time that the restarted infrastructure will reflect. Essentially, this is the roll-back that will be experienced as a result of the recovery. The most desirable RPO would be the point just prior to the data loss event. Making a more recent recovery point achievable requires increasing the frequency of synchronization between the source data and the backup repository.[13]
Recovery time objective (RTO)
The amount of time elapsed between disaster and restoration of business functions.[14]
Data security
In addition to preserving access to data for its owners, data must be restricted from unauthorized access. Backups must be performed in a manner that does not compromise the original owner's undertaking. This can be achieved with data encryption and proper media handling policies.
Limitations
An effective backup scheme will take into consideration the limitations of the situation.
Backup window
The period of time when backups are permitted to run on a system is called the backup window. This is typically the time when the system sees the least usage and the backup process will have the least amount of interference with normal operations. The backup window is usually planned with users' convenience in mind. If a backup extends past the defined backup window, a decision is made whether it is more beneficial to abort the backup or to lengthen the backup window.
Performance impact
All backup schemes have some performance impact on the system being backed up. For example, for the period of time that a computer system is being backed up, the hard drive is busy reading files for the purposes of the backup, and its full bandwidth is no longer available for other tasks. Such impacts should be analyzed.
Costs of hardware, software, labor
All types of storage media have a finite capacity with a real cost. Matching the correct amount of storage capacity (over time) with the backup needs is an important part of the design of a backup scheme. Any backup scheme has some labor requirement, but complicated schemes have considerably higher labor requirements. The cost of commercial backup software can also be considerable.
Network Bandwidth
Distributed backup systems can be affected by limited network bandwidth.
Implementation
Meeting the defined objectives in the face of the above limitations can be a difficult task. The tools and concepts below can make that task more achievable.
Scheduling
Using a job scheduler can greatly improve the reliability and consistency of backups by removing part of the human element. Many backup software packages include this functionality.
Authentication
Over the course of regular operations, the user accounts and/or system agents that perform the backups need to be authenticated at some level. The power to copy all data off of or onto a system requires unrestricted access. Using an authentication mechanism is a good way to prevent the backup scheme from being used for unauthorized activity.
Chain of trust
Removable storage media are physical items and must only be handled by trusted individuals. Establishing a chain of trusted individuals (and vendors) is critical to defining the security of the data.
Measuring the process
To ensure that the backup scheme is working as expected, the process needs to include monitoring key factors and maintaining historical data.
Backup validation
(also known as "Backup Success Validation") The process by which owners of data can get information regarding how their data was backed up. This same process is also used to prove compliance to regulatory bodies outside of the organization, for example, an insurance company might be required under HIPAA to show "proof" that their patient data are meeting records retention requirements[15]. Disaster, data complexity, data value and increasing dependence upon ever-growing volumes of data all contribute to the anxiety around and dependence upon successful backups to ensure business continuity. For that reason, many organizations rely on third-party or "independent" solutions to test, validate, and optimize their backup operations (backup reporting).
Reporting
In larger configurations, reports are useful for monitoring media usage, device status, errors, vault coordination and other information about the backup process.
Logging
In addition to the history of computer generated reports, activity and change logs are useful for monitoring backup system events.
Validation
Many backup programs make use of checksums or hashes to validate that the data was accurately copied. These offer several advantages. First, they allow data integrity to be verified without reference to the original file: if the file as stored on the backup medium has the same checksum as the saved value, then it is very probably correct. Second, some backup programs can use checksums to avoid making redundant copies of files, to improve backup speed. This is particularly useful for the de-duplication process.
Monitored Backup
Backup processes are monitored by a third party monitoring center. This center alerts users to any errors that occur during automated backups. Monitored backup requires software capable of pinging the monitoring center's servers in the case of errors. Some monitoring services also allow collection of historical meta-data, that can be used for Storage Ressource Management purposes like projection of data growth, locating redundant primary storage capacity and reclaimable backup capacity. The Wizards Storage Portal is an example of a solution that monitors IBM's well known Tivoli Storage Manager(TSM) solution.