Embedded - System On Chip (SoC)
Embedded - System On Chip (SoC) - Category Overview
Definition of Embedded - System On Chip (SoC)
Embedded System on Chip (SoC) refers to a highly integrated semiconductor device that combines multiple core computing components onto a single chip. These components typically include a processor (CPU), memory, input/output (I/O) interfaces, and specialized accelerators (e.g., GPU, DSP, or AI cores). SoCs are designed for embedded systems, where compact size, power efficiency, and high performance are critical. They serve as the brain of smart devices, enabling advanced functionality in applications such as IoT, automotive systems, industrial automation, and consumer electronics.
Types of Embedded SoC Products
This category encompasses a diverse range of SoC solutions tailored for different industries and performance requirements:
- Application-Specific SoCs: Optimized for tasks like AI inference (e.g., NVIDIA Jetson, Qualcomm AI Engine) or real-time control (e.g., industrial PLCs).
- General-Purpose SoCs: Flexible designs for broad use cases (e.g., ARM-based SoCs like Raspberry Pi Compute Modules).
- Wireless SoCs: Integrate connectivity (Wi-Fi, Bluetooth, 5G) for IoT devices (e.g., ESP32, Nordic Semiconductor SoCs).
- Automotive SoCs: Compliant with safety standards (ISO 26262), used in infotainment and ADAS (e.g., NXP i.MX, Renesas R-Car).
- FPGA-SoC Hybrids: Combine programmable logic with processors (e.g., Xilinx Zynq, Intel Cyclone V).
Purchasing Recommendations for SoCs
When selecting an SoC, consider:
1. Performance Needs: Match CPU/GPU cores, clock speeds, and memory bandwidth to your workload (e.g., edge AI vs. low-power sensors).
2. Power Efficiency: Critical for battery-operated devices; check TDP (thermal design power) ratings.
3. Connectivity & Peripherals: Ensure built-in interfaces (USB, PCIe, MIPI) align with your system design.
4. Software Support: Verify OS compatibility (Linux, RTOS, Android) and vendor-provided SDKs/drivers.
5. Longevity & Supply: Industrial/automotive projects may require extended lifecycle availability.
Why Choose This Category? SoCs reduce development complexity, accelerate time-to-market, and enable cutting-edge functionality in space-constrained designs. Browse our curated selection to find the ideal balance of integration, performance, and cost for your embedded application.
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M2S010S-TQG144
IC SOC CORTEX-M3 166MHZ 144TQFP
M2S050T-FCS325I
IC SOC CORTEX-M3 166MHZ 325BGA
XCZU2CG-1SFVC784I
IC SOC CORTEX-A53 784FCBGA
XC7Z014S-2CLG484E
IC SOC CORTEX-A9 766MHZ 484BGA
XCZU4CG-1SFVC784I
IC SOC CORTEX-A53 784FCBGA
XC7Z010-3CLG400E
IC SOC CORTEX-A9 866MHZ 400BGA
XCZU7EG-3FFVC1156E
IC SOC CORTEX-A53 1156FCBGA
M2S025TS-1FCSG325
IC SOC CORTEX-M3 166MHZ 325BGA
XC7Z030-2SBG485I
IC SOC CORTEX-A9 800MHZ 485FCBGA
XCZU2CG-2UBVA530I
IC SOC CORTEX-A53 530BGA
XCZU43DR-L1FFVG1517I
IC ZUP RFSOC A53 FPGA LP 1517BGA
XCZU9CG-L1FFVB1156I
IC SOC CORTEX-A53 1156FCBGA
XCZU15EG-2FFVB1156I
IC SOC CORTEX-A53 1156FCBGA
XCVC1902-2MSIVIVA1596
IC VERSAL AICORE FPGA 1596BGA
XCZU48DR-1FFVE1156I
IC ZUP RFSOC A53 FPGA 1156BGA
M2S050T-1VF400
IC SOC CORTEX-M3 166MHZ 400VFBGA
XC7Z035-3FFG900E
IC SOC CORTEX-A9 800MHZ 900FCBGA
M2S050T-1FCS325
IC SOC CORTEX-M3 166MHZ 325BGA
XCZU3CG-1SBVA484I
IC SOC CORTEX-A53 484FCBGA
XC7Z020-1CLG400C
IC SOC CORTEX-A9 667MHZ 400BGA