Kria K26 System-on-Module
by: AMD
The newest path to whole application acceleration, the K26 SOM is optimized for edge vision applications requiring flexibility to adapt to changing requirements. Available in Commercial and Industrial Grade variants for production deployment.
WHAT’S KRIA
Simplifying the Design and Productization of Edge Devices
Designed to Enable Smart City and Smart Factory Applications
- 3X vision AI performance and 2X performance-per-watt versus competing SOMs1
- Native ROS 2 support for 5X productivity for robotics and industrial automation
Out-of-the-Box Hardware Acceleration
- Leverage pre-built accelerated applications without needing FPGA design experience
- Tailor AI models and application code to your requirements
Production Qualified and Certified Commercial and Industrial Grades
- Commercial: operating range 0 to 85°C for smart camera, embedded vision,
tracking & identification - Industrial: operating range -40 to 100°C and ruggedized for extreme environments
Key Features
The K26 SOM features an exclusive, custom-built XCK26 SoC based on the Zynq™ UltraScale+™ MPSoC architecture, that has been configured for enhanced acceleration of vision AI applications.
| Area | Parameter | K26 |
|---|---|---|
| Form Factor | Dimensions (with heat spreader) | 77mm x 60mm x 11mm |
| Processor Unit & Acceleration | Application Processor | Quad-core Arm® Cortex®-A53 MPCore™ up to 1.5GHz |
| Real-Time Processor | Dual-core Arm Cortex-R5F MPCore up to 600MHz | |
| Graphics Processing Unit | Mali™-400 MP2 up to 667MHz | |
| Video Codec Unit (VCU) | 1 - up to 32 streams (total resolution ≤ 4Kp60) | |
| Trusted Platform Module (TPM) | Infineon 2.0 | |
| Memory | On-Chip* | 26.6Mb On-Chip SRAM |
| On-SOM | 4GB 64-bit DDR4 (non-ECC) and 16GB eMMC | |
| Connectivity | High-Speed PS Connectivity (GTR) | PCIe® Gen2 x4, 2x USB3.0, SATA 3.1, DisplayPort, 4x Tri-mode Gigabit Ethernet |
| General PS Connectivity (MIO) | 2xUSB 2.0, 2x SD/SDIO, 2x UART, 2x CAN 2.0B, 2x I2C, 2x SPI, 4x 32b GPIO | |
| Transceivers | GTH 12.5Gb/s Transceivers | 4 (PCIe Gen3 x4, SLVS-EC, HDMI 2.0, DisplayPort 1.4) |
| GTR 6Gb/s Transceivers | 4 | |
| I/O Count | PS MIO (1.8V) | 52 |
| PL High-density (HD) I/O (3.3V) | 69 | |
| PL High-performance (HP) I/O (1.8V) | 116 | |
| Programmable Logic | System Logic Cells (K) | 256 |
| DSP Slices | 1,248 | |
| Power & Thermal | Typical Power | 7.5W |
| Maximum Power** | 15W | |
| Thermal Interface | Passive (Heat spreader) | |
| Speed and Temp Grade | Commercial | -2 speed grade, low voltage and 0 to 85°C temperature range |
| Industrial | -2 speed grade, low voltage and –40 to 100°C temperature range |
Default
Default
Title
Document Type
Date
| KV260 Vision AI Starter Kit | KR260 Robotics Starter Kit | K26 Commercial SOM | K26 Industrial SOM | |
|---|---|---|---|---|
| Product Type | Development / Evaluation | Fully Qualified and Certified Commercial Grade Production Module | Fully Qualified and Certified Industrial Grade Production Module | |
| Operating Temp Range | 0°C to 35°C | 0°C to 85°C | –40°C to 100°C | |
| Target Use | Run Application Designs and Demos with Ease | Plugs into a carrier card designed for specific target application which includes Smart City, Robotics, Machine Vision, Industrial Communication & Control | ||
| Warranty | 90 days | 2 years | 3 years | |
| Expected Product Lifetime | - | - | 5 years | 10 years |
| Price | $199 | $349 | $300 | $420 |
Kria K26 Carrier Card Design Resources
| File Name | Description | File Type |
|---|---|---|
| xtp680-kria-k26-3d-cad-model.zip | Kria K26 SOM 3D CAD Model | ZIP |
| xtp685-kria-k26-som-xdc.zip | Kria K26 SOM XDC | ZIP |
| xtp688-kria-k26-trace-delay.zip | Kria K26 SOM Trace Delays | ZIP |
| xtp717-kria-k26-thermal-model.zip | Kria K26 SOM Thermal Model | ZIP |
| xtp748-kria-som-schematic-review-checklist.zip | Kria K26 SOM Schematic Review Checklist | ZIP |
| https://xilinx-wiki.atlassian.net/wiki/spaces/A/pages/1641152513/Kria+K26+SOM | Kria K26 SOM Developer Wiki | N/A |
| Obtainable directly in Vivado Board Store https://github.com/Xilinx/XilinxBoardStore/wiki/Xilinx-Board-Store-Home |
Kria K26 SOM Vivado Board File | N/A |
Kria KR260 Carrier Card Design Resources
| File Name | Description | File Type |
|---|---|---|
| xtp744-kr260-carrier-card-3d-cad-model.zip | Kria KR260 Starter Kit Carrier Card 3D CAD Model | ZIP |
| xtp756-kr260-allegro-board-source.zip | Kria KR260 Starter Kit Carrier Card Layout | ZIP |
| xtp743-kr260-schematic.zip | Kria KR260 Starter Kit Carrier Card Schematic | ZIP |
| xtp750-kria-kr260-carrier-card-schematic-source.zip | Kria KR260 Starter Kit Carrier Card Schematic Source | ZIP |
| xtp757-kria-kr260-carrier-card-bom.zip | Kria KR260 Starter Kit Carrier Card BOM | ZIP |
| Use Board Awareness in Vivado | Kria KR260 XDC | N/A |
| Obtainable directly in Vivado Board Store https://github.com/Xilinx/XilinxBoardStore/wiki/Xilinx-Board-Store-Home |
Kria KR260 Starter Kit Vivado Board File | N/A |
Kria KV260 Carrier Card Design Resources
| File Name | Description | File Type |
|---|---|---|
| xtp679-kria-k26-carrier-card-3d-cad-model.zip | Kria KV260 Starter Kit Carrier Card 3D CAD Model | ZIP |
| xtp681-kria-k26-carrier-card-layout.zip | Kria KV260 Starter Kit Carrier Card Layout | ZIP |
| xtp682-kria-k26-carrier-card-schematic.zip | Kria KV260 Starter Kit Carrier Card Schematic | ZIP |
| xtp683-kria-k26-carrier-card-schematic-orcad.zip | Kria KV260 Starter Kit Carrier Card Schematic Source | ZIP |
| xtp713-kria-k26-carrier-card-bom.zip | Kria KV260 Starter Kit Carrier Card BOM | ZIP |
| Use Board Awareness in Vivado | Kria KV260 XDC | N/A |
| Obtainable directly in Vivado Board Store https://github.com/Xilinx/XilinxBoardStore/wiki/Xilinx-Board-Store-Home |
Kria KV260 Starter Kit Vivado Board File | N/A |
Power Design Manager and Documentation
| Description | File | Rev | Date |
|---|---|---|---|
| Power Design Manager Install File |
Windows Installer | 1.0 | 2021/11/19 |
| Linux Installer | |||
| Power Design Manager User Guide | ug1556-power-design-manager.pdf | 1.0 | 2021/11/19 |
Another critical part of creating the SOM carrier card is to ensure that the thermal solution is capable of keeping the SOM within its thermal limits. The thermal models below can be used in conjunction with Power Design Manager and support Siemens Flotherm or Ansys Icepak.
Thermal Design Files and Documentation
| Description | File | Rev | Date |
|---|---|---|---|
| UG1090 Kria K26 SOM Thermal Design Guide | ug1090-k26-thermal-design_WtMkX.pdf | 1.0 | 2021/11/19 |
| XTP717 Kria K26 Thermal Model | Kria K26 Thermal Model.zip | 1.0 | 2021/11/19 |
STARTER KITs
KV260 Vision AI Starter Kit
Available Now
The KV260 Vision AI Starter Kit is an out-of-the-box ready development platform for AI, embedded SW & HW developers. Designed for Vision AI applications, the KV260 is the fastest way to develop unique solutions for production volume deployment with the K26 SOM.
KR260 Robotics Starter Kit
Available Now
The KR260 Robotics Starter Kit integrates high-performance industrial interfaces and features native ROS 2 support. Designed for robotics and industrial applications, the KR260 is the fastest way to develop intelligent factory solutions for production volume deployment with the K26 SOM.
Powering Electric Drive Control & Efficiency with Adaptive Computing
Kria™ adaptive System-on-Module (SOM) devices from AMD play an important role in electric drive control. They can optimize performance, help a motor run more efficiently, reduce power consumption, mitigate noise, cut vibration, and detect potential failures before they happen. Download our new motor control eBook to learn more!
Accelerate Your AI-Enabled Edge Solution with Adaptive Computing
Learn all about adaptive SOMs, including examples of why and how they can be deployed in next-generation edge applications, and how smart vision providers benefit from the performance, flexibility, and rapid development that can only be achieved by an adaptive SOM.
Adaptive Computing in Robotics
Demand for robotics is accelerating rapidly. Building a robot that is designed to be safe and secure and can operate alongside humans is difficult enough. But getting these technologies working together can be even more challenging. Complicating matters is the addition of machine learning and artificial intelligence, which is making it more difficult to keep up with computational demands.
Roboticists are turning toward adaptive computing platforms, which offer lower latency and deterministic, multi-axis control with built-in safety and security features on an integrated, adaptable platform that is expandable for the future. Read the eBook to learn more.
Questions?
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