What Is Storage Spaces?

If you're anything like that, you've got a ton of different storage hardware mediums lying around. You've reached your external hard drives, flash memory sticks, and maybe even some old-fashioned floppy disks. Now, there are many ways you can use those things. You could store your music on one drive, your photos on another, and your documents on the third. What if you could combine them into a single virtual data pool? That's precisely what Storage Spaces is designed to do: turn all your storage hardware mediums into one extensive virtual collection of data you can access from any device connected to your network. If you've ever wanted to know what it feels like to be a wizard, then Storage Spaces is for you. With Storage Spaces, users can create virtualized logical storage drives on pooled storage capacity. Each virtual/logical drive or storage space may be used as a typical disk drive with the option to format, secure and segregate data. Data resiliency and redundancy are provided through a two or three-way mirroring technique, where two or three copies of each data object are maintained on separate disks. Storage Spaces also incorporate a thin provisioning technique. The collective capacity of physical hard drives is extended according to their actual size when converted into a pool or space. You get all the benefits of having your cloud server at home (and no one will ever know how much porn you have stored there) but none of the hassle that comes with it! Storage Spaces is based on the Windows Home Server Drive Extender technology, providing similar features but lacking data resiliency and integrity. If one of your drives failed or was removed without being adequately ejected first, it could cause catastrophic failure for everyone who used the pool at the time. With Storage Spaces, however, all data is stored redundantly across each disk so that even if one fails or is improperly ejected from its enclosure (as often happens with USB flash drives), no user data will be lost or corrupted, and this also means that users don't need.

By TechDogs Editorial Team

Related Terms by Storage

Scanning Electron Microscope (SEM)

The scanning electron microscope combines two of the most valuable types of microscopes: They function in the same way as a standard microscope but are superior. Imagine you are looking at the very tip of your nose right now and attempting to see what's there. To get a close look at those minuscule hairs, you would need a powerful microscope, and if you squinted your eyes that intently at your face, you would probably have a headache. Imagine instead employing a scanning electron microscope, in which case the electrons would perform all the work for you. Since electrons make it possible for visual display results to have better integrity and resolution, objects can be seen more clearly and be used for cutting-edge research and engineering. You may not believe anything like this might be beneficial in regular life, but it absolutely is. We wouldn't be able to see how the tiny parts of bugs work together to form a whole, nor would we be able to see how much space there is between each atom in our bodies if we didn't have scanning electron microscopes. We would know nothing about our world if it weren't for the scanning electron microscopes that are currently in use. An electron beam is used to analyze whatever is being viewed in a scanning electron microscope, which is a type of microscope. It is also known as an SEM, and it is really interesting. The SEM traces the paths that electrons go through in an experiment. An electron gun is responsible for releasing electrons, which can be thought of as a light bulb that releases electrons rather than photons (light particles). Then, after passing through a few different components, such as scanning coils and a detector for backscattered electrons. You now possess some images obtained from the SEM! The backscattered electrons are transformed into signals and then delivered to a display screen. So as you're doing it, you're looking at photographs of your product on your computer or television screen - that's awesome!

Secure Hash Algorithm (SHA)

Secure Hash Algorithm is a set of algorithms developed by the National Institutes of Standards and Technology and other government and private parties. Cryptographic hashes (or checksums) have been used for electronic signatures and file integrity for decades. However, these functions have evolved to address some of the cybersecurity challenges of the 21st century. The NIST has developed a set of secure hashing algorithms that act as a global framework for encryption and data management systems. The initial instance of the Secure hash Algorithm (SHA) was in 1993. It was a 16-bit hashing algorithm and is known as SHA-0. The successor to SHA-0, SHA-1, was released in 1995 and featured 32-bit hashing. Eventually, the next version of SHA was developed in 2002, and it is known as SHA-2. SHA-2 differs from its predecessors because it can generate hashes of different sizes. The whole family of secure hash algorithms goes by the name SHA. SHA-3, or Keccak or KECCAK, is a family of cryptographic hash functions designed by Guido Bertoni, Joan Daemen, Michaël Peeters, and Gilles Van Assche. SHA-3 competition to develop a new secure hash algorithm was held by the United States National Security Agency (NSA) in 2007. To be a super safe and fast hashing algorithm, SHA3 was developed from this contest. The evolution of cybersecurity has led to the development of several "secure hash algorithms." Security is a crucial concern for businesses and individuals in today's digital world. As a result, many types of encryption have been developed to protect data in various scenarios. One of these is hash algorithms. All secure hash algorithms are part of new encryption standards to keep sensitive data safe and prevent different types of attacks. These algorithms use advanced mathematical formulas so that anyone who tries to decode them will get an error message that they aren't expected in regular operation.

Segregated Witness (SegWit)

It is time to get this party started! SegWit is an agreement implemented in the Bitcoin cyber currency community. It is also a soft fork in the Bitcoin chain and has been widely accepted by miners and users. So what does it all mean? In short, if you are running a node (a piece of software that helps keep the Bitcoin network stable), you need to upgrade your software by April 27th, or else your node will stop working. SegWit was activated as part of a hard fork on August 24th, 2017. The most important thing to note about SegWit is that it fixes transaction malleability, which has plagued miners and users for years. However, you do not need to worry if you do not want to upgrade your software. You will still be able to use Bitcoin just fine! It is confusing, but it is not that confusing. Segregated Witness (SegWit) is a proposal to improve Bitcoin implemented in August 2017. It allows for more transactions per block, which means lower fees and faster transactions.SegWit2x is a proposal that would include a hard fork months after the initial adoption of SegWit, creating two bitcoins. One of these versions would have SegWit, and one wouldn't, but both would be called "Bitcoin" and act as separate currencies. BIP 148 is another proposal that includes a user-activated hard fork and proposes implementing SegWit.SegWit is a soft fork, not a hard fork. SegWit is a technical improvement that allows more transactions to be processed simultaneously, making the network faster and more efficient. A hard fork is when developers propose changes to the protocol. If most users accept those changes, there will be two versions of that particular cryptocurrency, one for each side. The Bitcoin Cash (BCH) chain split from Bitcoin in August 2017 as an example of a crypto hard fork. Bitcoin Cash is the result of a hard fork.

Trending Definitions

Limited Connected Device User Interface (LCDUI)

Limited Connected Device User Interface, or LCDUI for short. It's a fancy saying, "the interface on your smartwatch or another small device that's too tiny for a full-blown user interface". You know, those little screens that make you feel like you need a microscope just to read them? Yeah, those. So why do we need an LCDUI, you ask? Well, it's all about making the most of our limited space. When dealing with a screen the size of a postage stamp, you can't have all the bells and whistles of a full-sized user interface. So we have to get creative. Enter the LCDUI. It's a specialized interface for small screens, with limited real estate and input options. Think of it like a tiny, stripped-down version of a full-sized UI. It's got just the essentials - the things you need to get the job done, and nothing more. #SmallButMighty The cool thing about the LCDUI is that it's not just about making things smaller. It's also about making things simpler. By stripping away all the unnecessary elements, we can create a UI that's easy to navigate and use, even on a tiny screen. That means big, chunky buttons and simple, straightforward menus that don't require a degree in computer science. #SimplicityIsKey Of course, designing an LCDUI has its challenges. We must be creative in finding ways to fit all the necessary functionality into a limited space. We must be careful not to overload the user with too much information or options. When done right, an LCDUI can be beautiful - a miniature work of art that packs a big punch. #DesignChallenges So the next time you're struggling to make sense of the tiny screen on your smartwatch or other connected devices, remember the hardworking designers who put in the effort to create an interface that works despite its limitations. Who knows, maybe we'll be able to pack all the functionality of a full-sized UI into a screen the size of a postage stamp. Hey, a tech lover can dream, can't they? #TinyButMighty #UIWizardry #DesignThinking

Email Encryption Gateway

A mail encryption gateway is a device that encrypts outgoing mail decrypts incoming mail, and controls spam. Get this appliance-based solution today! An email encryption gateway is a dedicated appliance that connects a mail server to the Internet and encrypts outgoing messages. Hence, data traveling between the mail server and recipients remain secure. Once encrypted, data travels through a standard outbound gateway from the corporation's network to the Internet. If an unauthorized person attempts to intercept data in transit, it will be useless because any attempt at decryption fails. The new digital certificate issued by Comodo will provide increased security and help your customers feel more confident about sending sensitive information via email. While some email encryption gateway vendors provide a cloud service, most vendors offer an appliance or virtual appliance for companies to deploy in their own data center. Encryption gateways are installed on server computers at the demilitarized zone (DMZ), forming a protective layer of security between the Internet and your organization's networks. They allow you to encrypt all communications with email recipients off-site while decrypting incoming messages. No one wants their confidential corporate data to end up in the wrong hands. Instead of encrypting your email, why not enlist the help of a mail gateway? A mail gateway combines the functions of encryption, decryption, spam-blocking and virus scanning with other features. Unlike other forms of encryption, these gateways often also serve as a mail proxy or firewall, ensuring that outsiders can't access your data. Email encryption is a growing operational concern for enterprise IT teams. It can be challenging to get end-user computers and mobile devices to comply with company security policies, whether it's due to user resistance, lack of technical know-how, or outdated software. With FortMail's email encryption gateway solution, you can secure all outgoing emails automatically according to configurable rules that eliminate the need for client software. Let's face it, and when it comes to something as crucial as email security, you want a solution that is both robust and easy to maintain. In recent years, the encryption gateway has also become virtualized, meaning that virtual solutions do not require actual gateway hardware.