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Lynx & ENSCO Demonstrate Avionics Solutions at DSEI JAPAN 2019

Picture of Dan Westerberg | Senior Systems Engineer Dan Westerberg | Senior Systems Engineer : Nov 18, 2019 2:29:00 PM

Multi-core Avionics Demo Lynx MOSA.ic™ FAA Safety Certification MCP Systems Architecture embedded systems development real-time

The most formidable challenges of modern avionics development programs are often centered around the safety certification process and the corresponding requirements and costs. Equally as challenging to any large development program are the design and implementation phases where the software application comes to life as it is realized on the target system environment. These phases can be compromised by:

Inevitable schedule pressures
The management of critical path requirements and availability between interrelated software components
Potential mismatches between an application's requirements and a less-than-ideal target operating environment

Simplifying Software Systems Using the Modular Open Systems Approach (MOSA)

The challenges listed above can be addressed with a robust architectural approach that minimizes overall system complexity by:

Decomposing large, complex software applications into smaller, comprehensible, reusable software components
Realizing those more manageable components in an operating environment best suited to the component’s requirements

This week at DSEI Japan 2019, Lynx Software Technologies and Ad-Sol Nissin Corp., our long-time strategic partner and distributor, are demonstrating how the LYNX MOSA.ic™ modular development & integration framework addresses these challenges through its Modular Open System Approach (MOSA) for simplifying the development and integration of complex, safety-critical avionics systems.

LYNX MOSA.ic™ and its Architectural Configuration Policy provides the ability to strictly partition and assign the resources of a CPU and surrounding embedded system to independent guest operating environments that reside in uniquely isolated virtual machines called ‘rooms’. Guests are provided direct, protected access to assigned hardware resources, such as a GPU or NIC, and have sole responsibility for the driver-level hardware control of the assigned resource.

The Architectural Configuration Policy also provides the ability to specify protected, inter-partition communication (IPC) shared memory pathways between guests, called ‘passageways’. Each Guest represents an independent software component inter-working with other guests in a distributed, modular software architecture.

LYNX MOSA.ic™ Addresses Avionics Challenges

Using LYNX MOSA.ic™ to modularize an avionics application into independent software components, provides the following benefits:

Run multiple independent, isolated software components of mixed-criticality on a single multi-core processor
Minimize system complexity by choosing operating environments that best meet the requirements of each modular application component (perhaps a bare-metal or RTOS Environment A is required for a high assurance, safety-critical application, while a separate, independent embedded Linux Environment B may sufficiently meet the requirements of a less critical application)
Connect independent environments according to your system design, using shared memory and inter-partition communication (IPC) mechanisms, such as FIFO

In collaboration with our partner ENSCO Avionics, Inc., the demonstration on display in our booth at DSEI Japan 2019 (see diagram below) highlights this modular approach to avionics design using LYNX MOSA.ic™ to host two guest environments:

An IData® Tool Suite avionics display application running on an enterprise-grade Linux
LynxOS-178® Real-Time Operating System (RTOS), running a flight data simulation application

ENSCO IData Diagram Draft 01.jpg

LynxOS-178®—A Component of LYNX MOSA.ic™ Framework

LynxOS-178^® is a native POSIX^®hard real-time partitioning operating system developed and certified to FAA DO-178C DAL A safety standards. In the displayed demonstration, the LynxOS-178^® guest instance is running a POSIX^®-based application that is generating simulated flight data and sending it to the IData® guest and avionics displays via a shared memory inter-partition communication FIFO.

This modular approach to the software architecture highlights the ability to develop safety-critical, high assurance applications in an independent, isolated processing domain that is not reliant upon or impacted by applications that may not have the same high-assurance requirements.

About the ENSCO Avionics IData^® Tool Suite

The ENSCO IData^® Tool Suite allows for the rapid development of complex avionics display and mapping solutions, using their “Data Driven Architecture and Design Once, Deploy to Many” philosophy. For the demonstration on display, a Linux runtime environment was selected as a readily available, robust development environment for developing the IData^® display application.

Once development is complete, the IData^® Tool Suite makes it straight-forward to re-target the application, without requiring design changes, into a suitable, safety-certifiable environment, such as Lynx’s LynxOS-178^® certified RTOS. With LYNX MOSA.ic™, changing the IData^® underlying runtime guest from a Linux environment to an RTOS environment is a simple matter of updating the LYNX MOSA.ic™ Architectural Configuration Policy, recompiling the design, and deploying the updated software image to the target system.

Lynx and ENSCO at DSEI Japan 2019

Come visit us at Stand A194 at DSEI Japan 2019 for more information on how the LYNX MOSA.ic™ modular development & integration framework and the ENSCO Avionics IData^® Tool Suite can address the safety-critical, high assurance requirements of your next project. If you are unable to attend DSEI Japan 2019, please contact us at inside@lynx.com or simply click the Get Started button below. We’d love to talk to you about your project and possibly schedule a free whiteboarding session.