Thin client

In using cloud-based architecture, the server takes on the processing load of several client sessions, acting as a host for each endpoint device. The client software is narrowly purposed and lightweight; therefore, only the host server or server farm needs to be secured, rather than securing software installed on every endpoint device (although thin clients may still require basic security and strong authentication to prevent unauthorized access). One of the combined benefits of using cloud architecture with thin client desktops is that critical IT assets are centralized for better utilization of resources. Unused memory, bussing lanes, and processor cores within an individual user session, for example, can be leveraged for other active user sessions.

The simplicity of thin client hardware and software results in a very low total cost of ownership, but some of these initial savings can be offset by the need for a more robust cloud infrastructure required on the server side.

An alternative to traditional server deployment which spreads out infrastructure costs over time is a cloud-based subscription model known as desktop as a service, which allows IT organizations to outsource the cloud infrastructure to a third party.

TA7 thin client by Gigabyte

Thin client computing is known to simplify the desktop endpoints by reducing the client-side software footprint. With a lightweight, read-only operating system (OS), client-side setup and administration is greatly reduced. Cloud access is the primary role of a thin client which eliminates the need for a large suite of local user applications, data storage, and utilities. This architecture shifts most of the software execution burden from the endpoint to the data center. User assets are centralized for greater visibility. Data recovery and desktop repurposing tasks are also centralized for faster service and greater scalability.

While the server must be robust enough to handle several client sessions at once, thin client hardware requirements are minimal compared to that of a traditional PC desktop. Most thin clients have low energy processors, flash storage, memory, and no moving parts. This reduces the cost and power consumption, making them affordable to own and easy to replace or deploy. Since thin clients consist of fewer hardware components than a traditional desktop PC, they can operate in more hostile environments. And because they typically don't store critical data locally, risk of theft is minimized because there is little or no user data to be compromised.

Modern thin clients have come a long way to meet the demands of today's graphical computing needs. New generations of low energy chipset and CPU (Central Processing Unit) combinations improve processing power and graphical capabilities. To minimize latency of high resolution video sent across the network, some host software stacks leverage multimedia redirection (MMR) techniques to offload video rendering to the desktop device. Video codecs are often embedded on the thin client to support these various multimedia formats. Other host software stacks makes use of User Datagram Protocol (UDP) in order to accelerate fast changing pixel updates required by modern video content. Thin clients typically support local software agents capable of accepting and decoding UDP.

Some of the more graphically intense use cases, remain a challenge for thin clients. These use cases might include the applications like photo editors, 3D drawing programs, and animation tools. This can be addressed at the host server using dedicated GPU cards, allocation of vGPUs (virtual GPU), workstation cards, and hardware acceleration cards. These solutions allow IT administrators to provide power-user performance where it is needed, to a relatively generic endpoint device such as a thin client.

To achieve such simplicity, thin clients sometimes lag behind desktop PCs in terms of extensibility. For example, if a local software utility or set of device drivers are needed in order to support a locally attached peripheral device (e.g. printer, scanner, biometric security device), the thin client operating system may lack the resources needed to fully integrate the required dependencies (although dependencies can sometimes be added if they can be identified). Modern thin clients address this limitation via port mapping or USB redirection software. However, these methods cannot address all scenarios. Therefore, it is good practice to perform validation tests of locally attached peripherals in advance to ensure compatibility. Further, in large distributed desktop environments, printers are often networked, negating the need for device drivers on every desktop.

While running local productivity applications goes beyond the normal scope of a thin client, it is sometimes needed in rare use cases. License restrictions that apply to thin clients can sometimes prevent them from supporting these applications. Local storage constraints may also limit the space required to install large applications or application suites.

It is also important to acknowledge that network bandwidth and performance is more critical in any type of cloud-based computing model. IT organizations must ensure that their network can accommodate the number of users that they need to serve. If demand for bandwidth exceeds network limits, it could result in a major loss of end user productivity.

A similar risk exists inside the data center. Servers must be sized correctly in order to deliver adequate performance to end users. In a cloud-based computing model, the servers can also represent a single point of failure risk. If a server fails, end users lose access to all of the resources supported by that server. This risk can be mitigated by building redundancies, fail-over processes, backups, and load balancing utilities into the system. Redundancy provides reliable host availability but it can add cost to smaller user populations that lack scale.

Popular providers of thin clients include Wyse Technology, NComputing, Dell (acquired Wyse in 2012), HP, IGEL Technology, LG and Samsung Electronics.

Zero client is also referred as ultra thin client, contains no moving parts but centralizes all processing and storage to just what is running on the server. As a result, it requires no local driver to install, no patch management, and no local operating system licensing fees or updates. The device consumes very little power and is tamper-resistant and completely incapable of storing any data locally, providing a more secure endpoint. While a traditional thin client is streamlined for multi-protocol client-server communication, a zero client has a highly tuned on board processor specifically designed for one possible protocol (PCoIP, HDX, RemoteFX, DDP). A zero client makes use of very lightweight firmware that merely initializes network communication through a basic GUI (Graphical User Interface), decodes display information received from the server, and sends local input back to the host. A device with such simple functionality has less demand for complex hardware or silicon, and therefore becomes less prone to obsolescence. Another key benefit of the zero client model is that its lightweight firmware represents an ultra-small attack surface making it more secure than a thin client. Further, the local firmware is so simple that it requires very little setup or ongoing administration. It's the ultimate in desktop simplification but the trade-off is flexibility. Most mainstream zero clients are optimized for one communication protocol only. This limits the number of host environments that a zero client can provide its users with access to.

Providers

Popular providers of zero clients include Wyse (Xenith), IGEL Technology, 10ZiG, Teradici, vCloudPoint.

Web-centric thin client

Web clients only provide a web browser, and rely on web apps to provide general-purpose computing functionality. However, note that web applications may use web storage to store some data locally, e.g. for "offline mode", and they can perform significant processing tasks as well. Rich Internet Applications for instance may cross the boundary, and HTML5 web apps can leverage browsers as run-time environments through the use of a cache manifest or so-called "packaged apps" (in Firefox OS and Google Chrome).

Examples of web thin clients include Chromebooks and Chromeboxes (which run Chrome OS) and phones running Firefox OS. O Chromebooks and Chromeboxes also have the capability of remote desktop using the free Chrome Remote Desktop browser extension, which means, other than being a web thin client, they can also be used as an ultra-thin client (see above) to access PC or Mac applications that do not run on the Chromebook directly. Indeed, they can be used as a web thin client and an ultra-thin-client simultaneously, with the user switching between web browser and PC or Mac application windows with a click.

Chromebooks are also able to store user documents locally – though, with the exception of media files (which have a dedicated player application to play them), all such files can only be opened and processed with web applications, since traditional desktop applications cannot be installed in Chrome OS.