Tutorials

Riviera-PROでどのようにMATLAB®インターフェースを使用するのかを解説します。

Riviera-PROでどのようにSimulink®インターフェースを使用するのかを解説します。

それぞれのTySOMボードは同一ではなく、異なるインタフェースとコネクタが含まれるため、独自のハードウェアプラットフォームが必要です。アルデックは、TySOMボードの使用を簡素化するために専用のSDxプラットフォームを用意しました。 それぞれのSDxプラットフォームには、Xilinxが提供するボードで使用可能な一連の簡単なサンプルをxfopencvライブラリで提供しています。 すべてのプロジェクトには、FPGAに変換されるC++関数も含まれています。

Pre-configured SDSoC Board Support Packages (BSP) for Aldec TySOM series boards coupled with FMC-ADAS daughter cards enable x5 BlueEagle camera links with 1280x720 default image resolution. Some reference applications provided by Aldec may require special 960x540 image resolution which can be forced from Linux devicetree description. This document provides step-by-step instructions describing image resolution switch process.

Riviera-PROでどのようにSystemCをシミュレーションするのかを解説します。

Learn about scripting interface in Riviera-PRO

TySOMプラットフォーム上で開発する場合、考慮することがたくさんあります。ハードウェア設計、ソフトウェア開発、組込みLinux開発、すべてTySOMのデザインフローの重要な部分です。

ボード・プログラミングとオペレーティングシステム起動を含む、TySOM-1-7Z030の準備方法

Details BASIC, ADVANCED BASIC, MEDIA, CAM-2-LCD STREAMING, and ALL-IN-ONE HDMI/LCD Embedded System Design.

Describes how to prepare a microSD card to use as a boot medium for running embedded Linux on a TySOM board, the two main options to set the root file system for an embedded Linux operating system, U-Boot as a second stage boot loader for an embedded Linux OS, etc.

ボード・プログラミングとオペレーティングシステム起動を含む、TySOM-2-7Z045の準備方法。

Delivers Reference Design Functional Overview, and outlines First Steps, External Dependencies, Processing System Configuration, Programmable Logic Fabric Customization, Implementation Flow, etc.

Describes how to prepare a microSD card to use as a boot medium for running embedded Linux on a TySOM board, the two main options to set the root file system for an embedded Linux operating system, U-Boot as a second stage boot loader for an embedded Linux OS, etc.

Hardware and software parts of embedded design can be successfully debugged separately using modern EDA tools. But when it takes to run both sides together, new system-level issues may appear. This tutorial shows how to use Xilinx SDK to create Linux userspace application and efficiently co-debug it with Vivado Logic Analyzer

The growing complexity of modern SoC designs along with the complexity of separate reusable IP cores requires SoC engineers to be familiar with the functional verification tools and approaches. This tutorial presents a step-by-step guide to involve Aldec Riviera-PROTM and ALINT-PROTM tools for the TySOM embedded development flow needs.

TySOM™ Educational Kit is designed for the university courses related to the embedded system design, digital system design and hardware design. The kit includes Riviera-PRO™ Advanced Verification Platform and a TySOM embedded development board It also comes with a selection of rich tutorials and reference designs from basic to advanced level to help professors and students start their projects using this kit.

This document describes how to prepare a microSD card to use as a boot medium for running embedded Linux on a TySOM board. The preferable model of microSD card is 16 GB class 10 card. It provides enough disk space and read/write access performance needed to run Desktop Linux based on Ubuntu 12.11 Linaro image. It is assumed that the user is running a Linux based OS host workstation and is familiar with basic command line commands and tools.

Internet of Things applications require fast, encrypted, and safe internet communication channels to send data and communicate with other devices. The best solution for this purpose is the cloud. This document describes all necessary steps to use Amazon Cloud in IoT applications with TySOM as an IoT gateway.

Basic Vivado design is intended to provide common board functionality by enabling UART and SDIO peripherals to run embedded Linux in it's minimal possible configuration. In this case, SDIO core is used to support microSD cards as Linux boot source and UART as main system console. Standard Vivado flow includes several stages to create hardware platform for the Zynq-7000 based board. All the reviewed projects in the current document use current basic platform for the further system expansion so the main stages will be covered only once. These stages will be reviewed in the order they appear. Actual used Xilinx Vivado tool version is 2014.2