Tag: removable media

How is your data organised on your computer, whether on its main disk or any removable storage connected to it>

A computer always needs to be able to hold programs and data in a non-volatile manner so users can get back to this data when they switch the computer on again. Here this has evolved through different methods and technologies that answered these needs in different ways.

What were these technologies that were available for home computers?

Initially, home-computer users used to have to use audio cassette tapes to store this data. Subsequently, the magnetic diskette, commonly known as the floppy disk due to it being like a piece of card, became the preferred storage method for computers. Typically, the better computer setups would end up with two floppy-disk drives so that two disks can be accessed at once.

A USB external hard disk

The early 1980s saw some manufacturers offer high-capacity fixed-disk drives, which were known as “hard disks” as a storage option for computers with this being preferred by business users. These storage devices earned this name as them being seen as an alternative to the old floppy disks.

Subsequently, Sony brought forward the hard-shelled 3.5” “micro-floppy” and this was brought out alongside a similar technology offered by Hitachi and a few other companies. It was to provide a higher-capacity smaller data-storage magnetic disk that was more rugged than the previous designs and appealed to the design of highly-portable computers.

The optical disk, which is based on CD technology, came in to being as an affordable software-distribution and large-data-distribution technology during the mid 1990s. Subsequently, solid-state non-moving flash storage came to fruition from the late 90s as a removable storage medium for digital cameras and PDAs but became more viable for regular computers since the late 2000s.

Since the magnetic disk came on the scene, there was an increased importance placed on organising where the data existed on these storage systems, with an emphasis on such concepts as file systems, volumes and folders or directories. This was because the various magnetic-disk systems were becoming more and more capacious and users needed to know where their data existed. Here, the file system effectively became a hierarchical database for the information you store on your computer and provided a logical relationship between the files and where the bits and bytes that represented them existed on the storage medium.

Desktop computers required the ability for the user to insert and remove any removable media at a moment’s notice but this required the user to be sure that all the data that was written to the medium before they could remove it. This is in contrast to what was required of mainframe and similar computer systems where an operator had to type commands to add the disk to the computer’s file system or remove it from the file system as part of physically attaching and detaching these disks.

This concept changed when Apple brought in the Macintosh computer which used the Sony 3.5” microfloppy disks. Here, they allowed you you to insert removable media in to that computer but required you to “drag it to the Trashcan” before the disk could be removed. Some advanced removable disk types like the Zip disk implemented this kind of removal in the Windows and other operating system by providing what has been described as a “VCR-style” eject routine due to its relationship to how you used an audio or video recorder. Here, you pressed the eject button on the disk drive which would cause all the data to be written back to the disk before the disk came out.

Now the modern computer has at least one hard disk and / or solid-state disk fixed inside it along with USB ports being used for connecting USB-connected hard disks or memory keys. You may also be inserting your camera’s SD card in to an SD-card slot on your laptop computer or in to an SD-card reader module that plugs in to your computer’s USB port if you were downloading digital images and videos. Some of you may even have an optical drive integrated in your computer or connected to it via a USB cable and use this for archiving data or playing CDs and DVDs.

Your operating system’s file manager

All the logical volumes available to a computer – representing hard disks with their logical partitions along with removable media

The operating system that runs your computer will have a file manager that allows you to discover and load your files or move, copy, rename and delete files amongst the logical volumes available to your computer. In Windows, this used to be known as File Manager, then became known as Windows Explorer but is now known as File Explorer. The Apple Macintosh describes this file manager simply as Finder.

This used to be a command-line task but since the arrival of the Apple Macintosh, the file manager is represented using a graphical user interface which shows a list of files, folders or logical volumes that you are dealing with.

Clicking on a folder or logical volume will bring up a screen to show you what is in that folder or logical volume. But clicking on a file will cause it to be opened by the default application or, in the case of a program, cause that program to run.

Moving or copying files nowadays is simply a drag-and-drop affair where you drag the files from the source to the destination, but you may have to hold down the Shift key or use the right-hand mouse button to modify a default move or copy action.

As well, the modern file managers have a “two-stage” delete action for files on a hard disk or other fixed storage where they end up in a “holding-bay” folder known as the Trashcan or Recycle Bin when you delete them. This is to allow you to find files that you may have unintentionally deleted. But to fully delete them for good, you have to delete the contents of this “holding-bay” folder, something you can do by right-clicking or Ctrl-clicking on this folder to bring up a context menu and selecting an “Empty” option.

What is my computer’s file storage system about

The logical volume

Most operating systems represent as their storage system every logical volume be it a removable disk or each partition of a hard disk as its own element. It was the only way to work in the early days of computing because each fixed or removable disk didn’t hold much in the way of data and was its own element. As hard disks became more capacious, there was a requirement to partition them or break a single physical hard disk in to multiple logical volumes because the operating systems of the early days couldn’t hold much data per volume. You can also set up some operating systems to present a folder on a NAS or file server available to you over a network to appear as a logical volume, a practice that was important before networks were commonplace and personal-computer operating systems could address network resources directly. All removable media are still represented with one logical volume per disk, card or stick.

Each logical volume would have the ability to be given a volume name and be represented as a distinct icon which is part of a “Devices”, “Volumes” or similar cluster in the file-management system that is part of the operating system. The icon is typically a crude representation of the storage medium that the logical volume exists on.

Windows, harking back to the Microsoft MS-DOS days, would also assign each logical volume a “drive letter” owing to the fact that each disk drive on the original IBM PC was assigned its own letter with A and B reserved for the floppy disk drives.

The Apple Macintosh represented on the right side of the Desktop screen a “disk” icon for each logical volume currently available to the system. But recent iterations of the Macintosh’s operating system provided a setting so that all of the logical volumes that represented the computer’s fixed storage didn’t appear as desktop icons.

The mid 1980s showed up a situation where an operating system had to identify what kind of disk a logical volume was on because hard disks were becoming more viable and a computer could have multiple disks of different kinds. This was also being augmented by the arrival of networks and file servers where you could “pool” your files on a common computer with larger storage, and CD-ROMs in the early 90s being a cheap way to deliver large amounts of software and data. Thanks to the graphical user interface, this was represented via an icon that represented the kind of disk being handled.

How are they represented?

In Windows, each logical volume, whether fixed or removable,is represented in Windows Explorer or File Explorer by an icon in the left hand panel under “This PC” or “Computer” or something similar depending on the version. If you click on this icon, you will see a list of all the logical volumes available to your computer.

On the Macintosh, you would normally have each of these volumes represented by an icon on the right hand side of your desktop, where you would click on that volume to invoke a Finder window to see all of the files in this volume. On the other hand, Finder would represent all of the volumes in a separate left-hand-side pane.

In both cases, each logical volume would be represented at least with its logical volume name and icon. With some systems, if there is a device that can hold removable media like an SD card reader, floppy disk drive or an optical drive, you will see that device listed but greyed out or de-emphasised if there is nothing in it.

Some operating systems like MacOS X may represent a removable volume like an SD card, USB memory key or optical disk with a distinct icon to highlight their removeability. This will typically be an “eject” symbol which you can click to safely remove that volume. Windows even lists the “eject” word in the right-click option menu for all of the volumes that are removable.

Folders

All the folders that exist on a hard disk, this time the system disk

The Macintosh and, subsequently, MS-DOS and Amiga brought around the concept of directories or folders as a way of organising data across increasingly-larger data volumes. Here, you could organise the data in to smaller clusters that relate to a common theme or purpose with the ability to create a folder within another folder.

Some operating systems like some versions of the Macintosh operating system allowed you to represent a folder with a graphical icon but this was used mainly by software developers when you installed software on the computer.

But all of the computers typically allocate a special folder on the main logical volume for storing all the programs that you run and, in some cases, even create a temporary folder for keeping data that a program stores on an as-needed basis.

How are they represented

On the graphical-user interface, these were represented as a folder icon that is  a part of how the contents of a logical volume was represented. Clicking on this folder icon will allow you to see the contents of that folder.

What is the main or system disk of your computer?

The Main Disk or System Disk for a Windows computer

The main disk on your computer, which is a hard disk or fixed solid-state-device, stores all the files that are to do with its operating system and all the applications you run on your computer. Such a disk is listed as C: in Windows or MACINTOSH HD on the Macintosh. It is also described as the system disk or the boot disk because it has the operating system that the computer has to load every time it is started, a process described as the “boot” process.

Where the programs that you run exist

It will also contain the data you create but all of the files needed to run the operating system and the applications will be kept in particular folders. For example, the  “Applications” or “Program Files” is kept aside for the applications and games the user installs, with each application you install creating its own subfolder of that folder. This is while a separate folder like “Windows” or “System” is kept for the operating system’s files. Some operating systems like MacOS may also use another folder for keeping plug-ins, fonts and similar common application resources while others may keep these with the applications / programs folder, usually as a subordinate folder.

Where the Desktop is represented

As well, all the icons and files that you store on the Desktop will be kept on a “Desktop” folder which represents everything that exists there.

The data you have created

But you will also end up with user-data space like “Documents”, “Photos” and the like where you save all of the data you create with your computer’s applications. Your e-mail program may store your emails in that folder or in a separate folder on this same disk.

Some operating systems, most notably Windows and earlier iterations of the Macintosh operating system, even let you create folders on the System Disk that aren’t earmarked for a purpose for you to use as your data folders. This also includes other programs keeping the user-created data in their own folders.

The secondary holding place for deleted files

Then there is the “Trashcan” or “Recycle Bin” folder which is used as a holding space for files you delete should you regret deleting them. When you delete a file from one of your folders on the main disk or other fixed disks in your computer, these files will end up in this “holding space”. Then if you want to remove them permanently, you have to delete them from this folder.

Removable Storage

USB storage device – an example of removable storage

All of the removable storage devices work on a freeform method of organising data across each of their logical volumes because there typically isn’t a requirement to keep certain folders for certain system processes.

This is except for memory cards associated with digital cameras because of the digital photography industry’s desire to implement a “Digital Camera File System”. Here, you have a DCIM folder for all digital-camera images and your camera will keep the pictures and videos you take in a subfolder of that DCIM folder, This was to simplify the searching process for digital images when you used a printer, photo-printing kiosk or electronic picture frame. There is also a MISC directory where DPOF print-order files are stored when you order photos to be printed using your camera’s control surface and either insert the camera card in to you multifunction printer or a photo-printing kiosk.

When you delete a file from removable storage, it is gone for good. As well, you need to make sure that you properly remove memory cards, USB memory keys and similar removable storage because most operating systems won’t write back all of the data changes to that storage device as they occur. Some operating systems like Windows allow you to immediately remove the classic floppy disks but most of them require you to use a “safely remove” or “eject” routine to properly write all the data to the removable medium before you can remove it. The Macintosh even allows you to drag the removable medium to the Trashcan to safely remove it.

Conclusion

The file system that your computer has is one of the key tenets of managing your data on your computer and it is about how your data is organised across multiple storage devices and within these storage devices.

USB storage device

As you use a computer, you will have to get in to the habit of removing or ejecting external or removeable media safely and in a proper way rather than just unplugging the device or pulling out the card.

What is this about safely removing or ejecting removeable storage?

Mainframe and similar large computer setups required the operating system to logically mount a tape or disk pack after the system operator installed the medium in the appropriate drive. This procedure makes the files on the medium available to the operating system and computer programs

USB hard disks are more critical with this procedure

Then when the medium was finished with, the system operator had to logically unmount the disk or tape which forced all files to he written back to the medium and the operating system to deem the files on the medium to be unavailable. This procedure was also simplified when the tape and disk-pack drives used electromechanical readiness detection like sensing when a lid or door was closed or a tape was past the heads to let the host computer know that they had media on board and were ready to work with it. It would then require the operator to logically mount the medium and make it available to the system’s programs, typically by typing a special “mount” command.

Desktop operating systems like MS-DOS did away with this to simplify the operating procedures for most people especially as they were used just by one user compared to the previous mainframe systems that were used by multiple concurrent users. It also allowed the use of low-cost disk and tape systems on these computers.

Here, these operating systems immediately wrote back all file changes to the disk when a file was created, modified or deleted. As well, if a program was after a file, it would perform a directory search to determine if the file was there on that disk and the operating system didn’t cache the removeable medium’s directory structure in to the host’s memory. In a lot of cases, the act of closing the disk drive’s door or inserting a 3.5” floppy disk cause the operating system to start reading the disk’s directory in to memory.

But the Apple Macintosh maintained a similar operating requirement to the larger computer systems where you had to logically remove a floppy disk or CD from the system typically by dragging the disk’s icon to the Trash before the computer ejected the disk. This was facilitated with these computers having floppy drives that implemented electromechanical load-eject mechanisms and no hardware “eject” button ever since the platform was created.

This was carried through with Zip drives and other similar removeable-media drives that used any form of electromechanical load-eject mechanisms. The presence of an eject button on these drives typically worked as a way of telling the operating system about an intent to remove the medium so it is logically unmounted and was also implemented with newer iterations of the MS-DOS / Windows operating system along with driver programs for earlier iterations of that operating system.

Similarly, those of you who have used the MiniDisc format, especially with an MD deck or a music system that has an integrated MD recorder, may notice this taking place when you are recording to these discs. What will happen with these decks is that a message will flash up on the unit’s display screen that it is writing all the changes to the disk when you press the eject button or power off the unit before the disk is available or the unit switches off. This makes sure that all of the recording and editing activity is properly committed to the disk and is intact.

Why was there a need to tell the operating system that you were intending to remove the medium

If removeable media is removed by surprise, there can be problems with the quality of the data that is written to the medium because the operating system and applications think that certain files on the medium are available to be worked with.

This can lead to corrupted files because all the changes to the file being worked on haven’t been written to the medium completely. There are also issues with the files being locked by programs that are writing back the necessary changes so that other programs can’t interfere with this process, and if a program hasn’t released these locks or committed all of the changes, the files may not be available for other programs to work with. In the worst cases, your computer can go in to a headspin if it is working with a file that exists one minute and doesn’t exist the next.

How do you safely remove USB removeable media?

Eject option in Windows Explorer

With a computer, you make sure that you have closed the files you are working on if you were using a program to work with them. Then you perform a safe-removal procedure that is dependent on your operating system.

Macintosh users simply drag the icon representing the removeable storage to the Trash icon at the bottom right of the Desktop screen. Then there will be a message to say that it is safe to remove the medium.

Windows users can do this in two ways. They can open Windows Explorer (File Explorer) or My Computer and right-click on the removeable storage which will be represented as its own drive letter. They then select the “Eject” option to begin safely removing the storage device.

Safely Remove Hardware icon in Notification area

The other method requires you to click on the Notification Area on the Taskbar and right-click on the “Safely Remove Hardware And Eject Media” icon. Here, you are presented with a list of USB storage devices that are connected to your computer. Click on the one you want to remove to begin safely removing it. In some cases, a physical device may represent two or more logical volumes (drive letters) because it has been partitioned as such. Here, you select the physical device’s name to safely remove that device.

Devices available to remove

USB-based removeable-media adaptors like floppy-disk drives, Zip drives and memory-card readers have the ability to safely remove a particular medium or the whole device. Here, you can click on the medium to remove the card or disk or click on the physical device name to remove the device before you unplug it.

Two logical devices in one physical device – the one that is written clearly is the one to remove

This is more important with those devices that handle multiple media types like some multi-slot memory-card readers or devices that have a combination of fixed and removeable storage options like some digital cameras and camcorders that have internal storage along with an SD or microSD card slot. In the latter situation, these devices would have fixed storage greyed out while the removeable storage is written in black.

I have prepared a PDF reference sheet about the procedure needed to safely remove your removeable media from your Windows computer. Download and print this and keep it by your computer if you or others need to know how to do this properly.

Android users would go to the Storage menu and select the “Unmount SD Card” option for the SD card or “Unmount Mass Storage” for storage devices connected to their mobile devices via USB “On The Go” connectivity.

It is safe to remove

For other devices like A/V devices that write to an SD card or USB memory key, you would have to go to the device’s menu and select the “Unmount”, “Remove” or, more likely, “Eject” option. This process would be analogous to ejecting a tape, CD or MiniDisc so you can work with another medium.

Of course, powering off the equipment properly such as selecting a logical shutdown option would prepare any media or removeable devices attached to the equipment for safe removal.

Conclusion

Once you know how to properly and safely remove media or detach USB storage devices from your computer or similar device, you can avoid situations which can place your computer’s reliability or the data on that medium at risk.

Article

SanDisk unleashes world’s first 128GB microSD card – storage, sandisk, Personal storage peripherals – Computerworld

From the horse’s mouth

SanDisk

Press Release

Product Page

My Comments

SanDisk has raised the bar with flash-memory storage by releasing the ultra-small 128Gb microSD card at the Mobile World Congress 2014 in Barcelona, Spain. This is seen as providing increased removable secondary-storage for Android or Windows phones and tablets due to its small footprint and is something I would see as important if we carry high-grade music and video files or complicated games on these devices and value the ability to “swap them out” as we see fit.

Tablets and Ultrabooks could also benefit from increased solid-state storage capacity

But I also see this as being suitable for more than the smartphone or tablet. This capacity is very much equivalent to what is available as a baseline all-SSD storage capacity for Ultrabooks and similar low-profile ultraportable notebook computers which typically run a full Windows deployment. Here, I could see this capacity appeal for smaller Wi-Fi portable NAS devices or it could be an encouragement to increase storage capacity in most dedicated-function devices like printers due to its small size and high capacity. This factor will be underscored for anyone who is working towards an extremely-low-profile design for a device rich in functionality such as the idea of a desktop multifunction printer having the same level of document control as a freestanding enterprise-grade multifunction printer.

Could raise the capacity of these low-profile NAS units very significantly

It also shows that the storage density for flash-based storage applications is increasing which could be a benefit for both fixed and removeable solid-state storage applications. For example, an Ultrabook or tablet could be ending up with 512Gb storage capacity furnished by flash memory rather than the mechanical hard disk as a product option. Or the low-profile Wi-Fi portable “media server” NAS that you take with you could carry your media library with you and serve it to your tablet, Ultrabook or car stereo from a 512Gb solid-state storage.

I would expect a lot more for high-capacity ultra-quick solid-state storage to become the norm for “there-and-then” data storage applications.

Articles – From the horse’s mouth

Press Release | Kingston

My Comments

I have had a look at the Kingston press release about the security of data held on USB flash drives and found that it was based on a Ponemon Institute study commissioned by Kingston. The main factor that I had observed was that the survey was based on data that represented the “big end of town” – the larger companies and government departments who typically handle a lot of high-stakes company and customer data.

Here I still find that small businesses and individuals are as at risk from removable-media data theft as are larger organisations. Most of these users would consider secure data storage as storing the confidential data on a USB memory key or external hard disk rather than on the computer’s hard disk. Here, they would keep that memory key or external hard disk locked in a desk drawer, filing cabinet or safe when the data is not needed. If the data isn’t changed or viewed often, like a valuables inventory, the USB memory key or external hard disk may be kept at a bank’s safe-deposit facility.

As well, the typical USB memory key can be attached to one’s keyring that has their house, car and business keys on it and a lot of these users may take advantage of the fact. These key rings are often at risk of loss due to absent-mindedness that can be common amongst us or theft as has been known to happen in the UK and Europe where houses have been broken into in order to steal the keys for powerful or expensive cars that are parked at these houses.

Of course, it is not just government and big business who handle or are responsible for “high-stakes” ultra-confidential data. Small businesses and individuals can also handle this kind of data, whether they provide services to these entities or not.

For example, I had provided technology assistance to a “one-person” business who valued fine art, antiques and collectables. This involved the handling of data relating to the collectable items and who owned the collectable items, as I commissioned newly-bought computers or trained her in computing techniques.

As well, individuals may need to keep copies of information pertaining to personal medical and legal issues where there is a strong emotional link. This information may be considered of high value where it concerns individuals who are in the “public eye” and the tabloid media are hungry for any bit of information about these individuals in order to run that exclusive “scoop”.

A common reality that this “enterprise-focused” article misses is that the typical small-business owner or personal user chooses and purchases their own computer hardware from retail. This is compared to larger organisations who maintain a dedicated IT team who is responsible for purchasing and maintaining the computer and communications technology for that organisation.

For this class of user, I would recommend that they use removable storage that is made by respected brands like Kingston, Verbatim, Sony or SanDisk. It may be worth knowing that some of the good retailers may resell these good brands under their own labels, usually in the premium end of those labels.

I would also recommend that you investigate the use of security-enabled encrypted USB memory keys. Here, I would look for those units that have continual software support from the vendor. This is important if you change your computing platform like what Apple hopes use do or move to newer versions of our current operating systems.

As well, you should make sure that you have good desktop security software on your computer. You could even get by with free programs like AVG or Microsoft Security Essentials. Even Macintosh users should make sure they run good anti-malware software on these computers especially as software threats are targeting this platform as well.

It is also worth making use of strong passwords or other data-locking options that the operating system or USB security software may provide for the confidential data. This may work in conjunction with the common practice of keeping the removable media under lock and key such as in a locked filing cabinet or safe.

What I fear is that a lot of press concerning data security tends to be focused at the big end of town and smaller users tend to be forgotten about. As well, a lot of the good-quality data-security options are often designed and priced out of the range of the small business operator or consumer even though there is a need for this level of data security amongst some of this class of user.