Intel® Stratix® 10 SX SoC FPGAs

Intel® Stratix® 10 SoCs, combine a quad-core ARM* Cortex*–A53 MPCore* hard processor system with the revolutionary Intel® Hyperflex™ FPGA Architecture to deliver the embedded performance, power efficiency, density, and system integration necessary for embedded applications.

See also: Intel® Stratix® 10 SX FPGAs Design SoftwareDesign StoreDownloadsDocumentationCommunity, and Support

Intel® Stratix® 10 SX SoC FPGAs

Intel® Stratix® 10 SX SoC FPGA

View Intel® Stratix® 10 SX SoC FPGAs and find product specifications, features, applications and more.

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Название продукта
Дата выпуска
Логические элементы (LE)
Блоки цифровой обработки сигналов (DSP)
Максимальная встроенная память
Варианты упаковки
Intel® Stratix® 10 SX 650 FPGA Launched 2013 612000 1152 52 Mb F1152
Intel® Stratix® 10 SX 400 FPGA Launched 2013 378000 648 32 Mb F1152
Intel® Stratix® 10 SX 1100 FPGA Launched 2013 1325000 2592 114 Mb F1760
Intel® Stratix® 10 SX 850 FPGA Launched 2013 841000 2016 72 Mb F1760
Intel® Stratix® 10 SX 1650 FPGA Launched 2013 1624000 3145 122 Mb F1760, F2397
Intel® Stratix® 10 SX 2100 FPGA Launched 2013 2005000 3744 138 Mb F1760, F2397
Intel® Stratix® 10 SX 2500 FPGA Launched 2013 2422000 5011 208 Mb F1760, F2397, F2912
Intel® Stratix® 10 SX 2800 FPGA Launched 2013 2753000 5760 244 Mb F1760, F2397, F2912

Features & Benefits

Intel® Stratix® 10 SoC Block Diagram

HPS: Quad-core ARM* Cortex*-A53 Hard Processor System
SDM: Secure Device Manager
EMIB: Embedded Multi-Die Interconnect Bridge




Quad-core ARM* Cortex*–A53 MPCore* processor cluster up to 1.5 GHz


Vector floating-point unit (VFPU) single and double precision, ARM* Neon* media processing engine for each processor

Level 1 Cache

32 KB L1 instruction cache with parity, 32 KB L1 data cache with error correction code (ECC)

Level 2 Cache

1 MB KB shared L2 cache with ECC

On-Chip Memory

256 KB on-chip RAM

System Memory Management Unit

System Memory Management Unit enables a unified memory model and extends hardware virtualization into peripherals implemented in the FPGA fabric

Cache Coherency Unit

Provides one-way (I/O) coherency that allows a CCU master to view the coherent memory of the ARM* Cortex*–A53 MPCore* CPUs

Direct Memory Access (DMA) Controller

8-channel direct memory access (DMA)

Ethernet Media Access Controller (EMAC)

3X 10/100/1000 EMAC with integrated DMA

USB On-The-Go Controller (OTG)

2X USB OTG with integrated DMA

UART Controller

2X UART 16550 compatible

Serial Peripheral Interface (SPI) Controller


I2C Controller

5X I2C

SD/SDIO/MMC Controller

1X eMMC 4.5 with DMA and CE-ATA support

NAND Flash Controller

1X ONFI 1.0 or later 8 and 16-bit support

General-Purpose I/O (GPIO)

Maximum 48 software-programmable GPIO

Timers 4X general-purpose timers, 4X watchdog timers
System Manager Contains memory-mapped control and status registers and logic to control system-level functions and other HPS modules
Reset Manager Resets signals based on reset requests from sources in the HPS and FPGA fabric, and software writing to the module reset control registers
Clock Manager Provides software-programmable clock control to configure all clocks generated in the HPS


Intel® SoC FPGAs are ARM* processor-based and inherit the strength of the ARM* eco-system. Intel, our ecosystem partners, and the Intel® SoC FPGA user community provide a wide range of options to meet your SoC FPGA development needs.


Информация о продукте и производительности


Comparison based on Stratix® V vs. Intel® Stratix® 10 using Intel® Quartus® Prime Pro 16.1 Early Beta. Stratix® V Designs were optimized using 3 step optimization process of Hyper-Retiming, Hyper-Pipelining, and Hyper-Optimization in order to utilize Intel® Stratix® 10 architecture enhancements of distributed registers in core fabric. Designs were analyzed using Intel® Quartus® Prime Pro Fast Forward Compile performance exploration tool. For more details, refer to Intel® Hyperflex™ FPGA Architecture Overview White Paper: Actual performance users will achieve varies based on level of design optimization applied. Tests measure performance of components on a particular test, in specific systems. Differences in hardware, software, or configuration will affect actual performance. Consult other sources of information to evaluate performance as you consider your purchase. For more complete information about performance and benchmark results, visit