Virtualization is technology that simulates hardware functionality to create software-based IT services like applications, servers, storage and networks.
Key topics about app virtualization:
Virtualization creates several virtual machines from one physical machine using software called a hypervisor. Because these virtual machines perform just like physical machines while only relying on one machine’s computing resources, virtualization allows IT organizations to run multiple operating systems on a single server (also known as a host). During these operations, the hypervisor allocates computing resources to each virtual machine as needed. This makes IT operations much more efficient and cost-effective. Flexible resource allocation like this made virtualization the foundation of cloud computing.
Here’s a common virtualization scenario: a business has three physical servers that each have a specific purpose: one supports web traffic, one supports company email, and one supports internal business applications. With each physical server only being used for its dedicated purpose, the business is probably only using one third of each server’s computing capacity—even though the business pays 100 percent of the server’s maintenance costs.
With virtualization, you could split one of the servers into two virtual machines and cut your maintenance costs by 33 percent. This means one server could handle email and web traffic, another could host all business applications, and the third could be retired to save costs or repurposed for some other IT service.
Cloud computing is the delivery of shared computing resources, software, or data as a service through the internet. Virtualization technology makes cloud computing possible by allocating virtual resources into centralized pools that can be easily managed and deployed using a layer of management software. Here’s how this works:
The difference between virtualization and cloud computing is virtualization is the technology allowing one server to provide capacity for many, and cloud computing allows different computers to access a shared pool of resources (which is a system made possible by virtualization).
Virtualization lets you have one machine serve as many virtual machines. This not only means you need fewer servers, but you can use the ones you have to their fullest capacity. These efficiency gains translate into cost savings on hardware, cooling, and maintenance—not to mention the environmental benefit of a lower carbon footprint.
Virtualization also allows you to run multiple types of apps, desktops, and operating systems on a single machine, instead of requiring separate servers for different vendors. This frees you from relying on specific vendors and makes the management of your IT resources much less time-consuming, allowing your IT team to be more productive.
Virtualization technology allows you to easily back up and recover your data using virtual machine snapshots of existing servers. It’s also simple to automate this backup process to keep all your data up to date. If an emergency happens and you need to restore from a backed up virtual machine, it’s easy to migrate this virtual machine to a new location in a few minutes. This results in greater reliability and business continuity because it’s easier to recover from disaster or loss.
Virtualization software gives your organization more flexibility in how you test and allocate resources. Because of how easy it is to back up and restore virtual machines, your IT team can test and experiment with new technology easily. Virtualization also lets you create a cloud strategy by allocating virtual machine resources into a shared pool for your organization. This cloud-based infrastructure gives your IT team control over who accesses which resources and from which devices, improving security and flexibility.
Servers are powerful machines designed to run specific, complex tasks. It’s common for IT to assign one task or application per server, but this can often result in underutilized capacity and higher maintenance costs. Server virtualization uses a hypervisor to partition your physical servers into multiple virtual servers, each running its own operating system. This lets you tap into the full power of your physical servers to significantly reduce hardware and operating costs.
App virtualization and desktop virtualization
application virtualization, users can run applications in an separate form regardless of the operating system in use. This is commonly used to run a Windows application inside a Linux or Mac operating system.With
Desktop virtualization allows users to simulate a workstation load in order to access a desktop remotely from a connected device such as a thin client at a desk. This means desktop virtualization enables more secure and portable access to data center resources.
App and desktop virtualization are popular because employees want to use their own devices and have access to their apps outside the office. At the same time, installing and maintaining apps and desktops on individual computers for each user is expensive and difficult to manage. Virtual apps and desktops offer a better solution by residing on a central server from which IT can deploy hundreds of simulated apps and desktops to users at once. This eliminates the need to install these apps and desktops (and any patches and updates) on each computer, and users can interact with virtual apps and desktops with the same user experience as native ones. Virtual apps and desktops also help organizations ensure regulatory compliance, disaster recovery, and business continuity.
With the widespread use of virtualized environments, many organizations are also virtualizing their networks. Network virtualization works by splitting available bandwidth into independent channels, each of which can be assigned to a server or device as needed. Network virtualization makes it easier to program and provision the network — including load balancing and firewalling — without having to touch the underlying infrastructure. IT typically manages the software components using a software-based administrator’s console. As computing needs evolve, network virtualization simplifies how IT rolls out, scales, and adjusts workloads.
Storage virtualization is when the physical storage from multiple devices on a network is pooled together in a unified virtual storage device that’s managed from a central console. To virtualize storage, you need virtualization software that can identify available capacity from physical devices and aggregate that capacity together in a virtual environment. For end users, virtual storage looks like a standard physical hard drive. Virtual storage is an important component in IT strategy like hyper-converged infrastructure and allows IT admins to streamline storage activities like backup, archiving, and recovery.
Data virtualization enables an application to access and leverage data without requiring details like where the data is physically located or how the data is formatted. This means you can create one representation of data from multiple sources without moving or copying that data. This data aggregation relies on data virtualization software to virtually integrate and visualize the data through a dashboard, allowing users to access large datasets from a single access point no matter where this data is stored. Data virtualization is important for any kind of analytics or business intelligence application.
Virtualization needs to be properly managed to keep your business’s data secure. Because virtual machines are copies of your servers, the more virtual machines you have the more targets you must protect from attackers who want to access your sensitive data. This security vulnerability makes it important to have a centralized management solution to monitor your virtual machines and protect them from unauthorized access. Virtualization security is an essential element of virtual desktop infrastructure, or VDI.
Workspace virtualization builds on application virtualization by bundling multiple apps together into one unified, digital workspace. This simulates an entire computing workspace on a virtual machine, allowing the users’ applications to interact the same way they would on a physical machine. For example, workspace virtualization would allow a user to embed a spreadsheet into a word processing document; in conventional application virtualization, each individual app is virtualized separately so they cannot interact with each other.
Workspace virtualization also allows users to keep their own settings and data inside the virtualized workspace. This means the virtualized workspace can be customized to each users in the same way as a physical machine. Users can also move their unique virtual workspace to a different operating system or machine while still preserving all their apps and data. This provides more flexibility in how users access the apps and data they need for work on the devices they choose.