OREANDA-NEWS. Fujitsu Laboratories Ltd. today announced the development of technology that allows for virtual desktops with larger screens, without upgrading existing network infrastructure.

Virtual desktops are being introduced to the factory floor as part of a change of work styles for development and production operations. Demands for larger screens in order to improve the operability of computer support for designing and analyzing increasingly complex products through computer-aided design (CAD) and computer-aided engineering (CAE) are rising, and there is a need for more efficient transmission technologies for sending those bigger screen images over the network.

Fujitsu Laboratories has now applied the high-quality video coding technology cultivated by Fujitsu to virtual desktop screen compression, and has developed technology that maintains image quality while cutting network bandwidth requirements roughly in half. This technology makes it possible to transmit roughly double the pixel count over existing network infrastructure, allowing for bigger, more detailed virtual desktops, and a more functional work environment.

Background

Virtual desktop technology runs the user's applications on a virtual server in a cloud environment and transfers desktop images to thin clients or other terminal devices. This helps keep ICT equipment costs down, maintains data security, and allows for a change in work styles. This technology is used primarily for office work, and more recently it has also started to be applied in development and production operations where products are designed and analysis applications such as CAD and CAE (Figure 1) are utilized.

Figure 1: Typical virtual desktop screens used in development and productionFigure 1: Typical virtual desktop screens used in development and production

Technological Issues

As products get more complicated, there are increasing demands to enlarge desktops in order to display product images in their entirety with visible details. With a virtual desktop, bigger desktops mean more network bandwidth is used when sending desktop images. In order to increase virtual desktop sizes without incurring the higher cost of enhancing network infrastructure, virtual desktop images need to be transmitted more efficiently.

About the Technology

Fujitsu has reduced the volume of transmitted virtual desktop data while maintaining high image quality without increasing network bandwidth.

The technology has the following key features

1. Optimization technology for high-quality compression and to reduce processing load for virtual-desktop screens

Using high-quality video coding technology developed by Fujitsu for transmitting high-resolution images inexpensively, the company developed optimization technology that compresses data while maintaining the high quality suited to the characteristics of virtual desktop screens, and that reduces processing load in response to image content.

Unlike broadcast images shot with a camera, a virtual desktop screen, with its extremely sharp lines drawn with CAD, CAE or other applications, has the characteristic of completely still-image backgrounds or other spaces. The technology maintains linear sharpness by optimized encoding mode selection, including block size and intra prediction mode, and largely obviates the processing load for still-image regions by optimized motion vector searches (Figure 2).

Figure 2: Optimizations for virtual-desktop screensFigure 2: Optimizations for virtual-desktop screens
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2. Technology for sharing reference images between still-image coding and video coding

Typically, static areas and moving areas within an image to be transmitted would be flagged separately, and appropriate compression schemes would be applied to each to maximize the overall compression of the data to send. This approach, however, results in increasing the volume of data when static and moving images frequently switch. To solve this problem, Fujitsu developed a function that shares encoded images for reference between still-image coding and video coding (Figure 3). This has the effect of reducing data volumes needed for switching, even when regions of the image to send frequently switch between still image and video, as is the case with screens where CAD or CAE software is being manipulated.

Figure 3: Referencing shared screensFigure 3: Referencing shared screens

Results

This technology had the effect of cutting network bandwidth roughly in half while maintaining image quality (Figure 4), making it possible to transmit a virtual desktop image with double the size (pixel count) while using the same network bandwidth. This enables larger virtual desktops without additional network infrastructure, for a more functional design environment.

Figure 4: Network bandwidth usedFigure 4: Network bandwidth used

Future Plans

This technology is due to be included in FTCP Remote Desktop, an engineering cloud, to be released in May 2015.

Fujitsu plans to continue introducing new video-coding technologies and developing technologies that will improve the performance of virtual desktops in manufacturing environments and elsewhere.

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