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- <h2>Dealing the hardware heterogeneity with <b>EmbeddedXEN</b>, a virtualization framework tailored to ARM based embedded systems.
-</h2>
- <p><i><p>EmbeddedXEN is a virtualization framework particularly efficient and tailored to ARM-based core embedded systems. While security and OS isolation are key features from conventional virtualizuation framework, the main concerns of EmbeddedXEN are the device heterogeneity and realtime aspects which are particularly important in the embedded world.<p>
-</p>EmbeddedXEN mainly relies on the original XEN architecture but with major differences in the way how the guest OS are handled: the hypervisor has been simplified, and only two guest OS (dom0 and domU) can run simultaneously; while dom0 is used to manage the native OS with drivers (original and backend of splitted drivers), a paravirtualized OS (domU) can have been cross-compiled on a different ARM device, and user applications can run seamlessly on the (virtualized) host device. Another important difference is that no user space tools are required to manage the VMs; the framework produces a compact single binary image containing both dom0 and domU guests which can be easily deployed. In this context, the Xenbus architecture has also been adapted accordingly.</p>
-<p>EmbeddedXEN can therefore enable porting an OS and its applications from an ARM embedded device, to a last generation ARM hardware such as HTC Smartphone for example.</p></i></p>
+ <h2>Dealing with Hardware Heterogeneity Using EmbeddedXEN, a Virtualization Framework Tailored to ARM Based Embedded Systems</h2>
+ <p><i><p>EmbeddedXEN is a particularly efficient virtualization framework tailored to ARM-based core embedded systems.</p>
+<p>While security and OS isolation are key features of conventional virtualizuation frameworks, the main concerns for EmbeddedXEN are device heterogeneity and realtime aspects, which are particularly important in the embedded world.</p>
+<p>EmbeddedXEN mainly relies on the original XEN architecture but with major differences in the way guest OS are handled: the hypervisor has been simplified, and only two guest OS (dom0 and domU) can run simultaneously; while
+dom0 is used to manage the native OS with drivers (original and backend splitted drivers), a paravirtualized OS (domU) can be cross-compiled on a different ARM device, and user applications can run seamlessly on the (virtualized) host device. Another important difference is that no user space tools are required to manage the VMs; the framework produces a compact single binary image containing both dom0 and domU guests, which can be easily deployed. The Xenbus architecture has been adapted to that context.</p>
+<p>EmbeddedXEN therefore allows the porting of an OS and its applications from an ARM embedded device to last generation ARM hardware, such as HTC Smartphone for example.</p>
+ </i></p>
<hr>
<p><b>Dr Daniel Rossier, Professor HES, University of Applied Sciences Vaud</b></p>
- <p><p>Daniel Rossier is a Professor in Embedded Computing Sciences at the University of Applied Sciences in Yverdon since 2003. Before his academic involvment, he has been working for more than 15 Years in various Swiss Companies mainly active in the field of telecommunications, multimedia and realtime control, as a Software Engineer and a Project Manager.</p>
-<p>In 2005, he joined the REDS Institute (Reconfigurable and Embedded Digital Systems) of HEIG-VD. His main research areas are operating systems (RTOS and GPOS), embedded virtualization, ARM technologies, and embedded software execution environments.</p>
-<p>He has led and participated in several CTI/KTI and EU research projects (IST, Eurescom, FP) in the field of realtime and self-adaptive network management, low-level software development (drivers, boot code, kernel subsystems) and embedded virtualization.</p>
-<p>Daniel Rossier is currently teaching operating systems, embedded computing (ARM programming) and realtime programming at the Bachelor level. In addition, he gives a Master course on the topic of advanced operating systems and embedded execution environments covering embedded virtualization, driver development and peripheral emulation. </p></p>
+ <p><p>Daniel Rossier has been a Professor in Embedded Computing Sciences at the University of Applied Sciences in Yverdon (Switzerland) since 2003. Before his academic involvement, he worked for more than 15 Years as a Software Engineer and a Project Manager in various Swiss Companies, mainly active in the field of telecommunications, multimedia and realtime control. In 2005, he joined the HEIG-VD REDS Institute (Reconfigurable and Embedded Digital Systems). His main research areas are operating systems (RTOS and GPOS), embedded virtualization, ARM technologies, and embedded software execution environments. </p>
+<p>He has led and participated in several CTI/KTI and EU research projects (IST, Eurescom, FP) in the field of realtime and self-adaptive network management, low-level software development (drivers, boot code, kernel subsystems) and embedded virtualization. </p>
+<p>Daniel Rossier is currently teaching operating systems, embedded computing (ARM programming) and realtime programming at the Bachelor level. In addition, he gives a Master course on the topic of advanced operating systems and embedded execution environments, covering embedded virtualization, driver development and peripheral emulation.</p></p>
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projects / people / larsk / xenproject-org-websites.git / commitdiff