Yuki Kinebuchi scite author profile

et al. 2008

Recently, the engineering cost of embedded systems is rapidly increasing due to growing sophistication of services. To deal with the problem, hybrid operating system environments have been proposed. This enables to run a RTOS and a general purpose OS concurrently and to reuse software resources on both of them. This approach is efficient in reducing engineering costs. We reconfigured the requirement for these hybrid operating system environment and build a new architecture which fulfills these requirements by using virtualization techniques. Our system provides the facilities to build multiple operating system environment easily. There are two contributions in our systems. One is that the modification cost of the guest OS is small. The second contribution is improvement in system availability by enabling guest OS to reboot independently. Although we used virtualization layer to construct a hybrid operating system environment, the performance overhead is considering small. Therefor our approach is very practical and efficient for recent sophisticated embedded systems.

Constructing a Multi-OS Platform with Minimal Engineering Cost

Morita

Makijima

et al. 2009

Abstract. Constructing an embedded device with a real-time and a general-purpose operating system has attracted attention as a promising approach to let the device balance real-time responsiveness and rich functionalities. This paper introduces our methodology for constructing such multi-OS platform with minimal engineering cost by assuming asymmetric OS combinations unique to embedded systems. Our methodology consists of two parts. One is a simple hypervisor for multiplexing resources to be shared between operating systems. The other is modifying operating systems to allow them to be aware of each other. We constructed an experimental system executing TOPPERS and Linux simultaneously on a hardware equipped with an SH-4A processor. The modification to each operating system kernel limited to a few dozen lines of code and do not introduce any overhead that would compromise real-time responsiveness or system throughput.

Task Grain Scheduling for Hypervisor-Based Embedded System

Sugaya

Oikawa

et al. 2008

Composition Kernel: A Multi-core Processor Virtualization Layer for Rich Functional Smart Products

Nakajima

Courbot

et al. 2010

Future ambient intelligence environments will embed powerful multi-core processors to compose various functionalities into a smaller number of hardware components. This makes the maintainability of intelligent environments better because it is not easy to manage massively distributed processors. A composition kernel makes it possible to compose multiple functionalities on a multi-core processor with the minimum modification of OS kernels and applications. A multi-core processor is a good candidate to compose various software developed independently for dedicated processors into one multi-core processor to reduce both the hardware and development cost. In this paper, we present SPUMONE which is a composition kernel for developing future smart products.

A Lightweight Monitoring Service for Multi-core Embedded Systems

Shimada

Courbot

et al. 2010

The recent increase in complexity and functionality in embedded systems makes them more vulnerable to rootkit-type attacks, raising the need for integrity management systems. However, as of today there is no such system that can guarantee the system's safety while matching the low-resource, real-time and multi-core requirements of embedded systems. In this paper, we present a Virtual Machine Monitor (VMM) based monitoring service for embedded systems that checks the actual kernel data against a safe data specification. However, due to the VMM and multi-core nature of the system, the guest OS can be preempted at any time, leading to the checking of potentially inconsistent states. We evaluated two approaches to solve this problem: detecting such invalid states by checking specific kernel data, and detecting system calls using the VMM.