FAQs

What is the price of your System on Module?

admin2025-05-17T16:41:39+00:00

What’s the MOQ of Customized Embedded Mianboard based on your SoMs?

admin2025-05-17T16:41:39+00:00

What Compoents does System on Module Contain?

admin2025-05-17T16:41:39+00:00Common System on module components include a CPU, RAM, flash memory, a power management unit, wired and wireless communication interfaces.

• Microcontroller, at least one microprocessor or digital signal processor (DSP) core
• Memory blocks including a selection of ROM, RAM, EEPROM and/or flash memory
• Timing sources
• Industry standard communication interfaces: such as USB, FireWire, Ethernet, USART, SPI, I²C
• Peripherals including counter-timers, real-time timers and power-on reset generators
• Analog interfaces including analog-to-digital converters and digital-to-analog converters
• Voltage regulators and power management circuits

What is the difference between CoM and SoM?

admin2025-05-17T16:41:39+00:00Computer on Module (CoM), also known as a System on Module (SoM), is a single physical embedded module integrated into a system function that contains core components including SoC, memory blocks, power unit etc., which then be connected to a suitable carrier board via pins to create a complete embedded mianboard/development board.

Why use system on module

admin2025-05-17T16:41:39+00:00System on Module (SoM) is a compact and integrated board that combines a microprocessor, memory, power management, and other essential components into a single module. It serves as a building block for creating more complex systems, thereby simplifying the design and development process. By leveraging SoMs, companies can significantly reduce both the time and cost associated with bringing new products to market.

• Faster Time-to-Market: SoMs can significantly reduce development time, allowing products to reach the market quicker. This can provide a crucial advantage in highly competitive industries.
• Reduced Development Risk: By using pre-tested and verified modules, the risk of encountering design flaws and unexpected issues is minimized compared to designing complex systems from scratch.
• Cost Reduction: SoMs can lower overall development costs by simplifying lifecycle management and reducing the bill of materials costs.
• Scalability and Flexibility: SoMs offer scalability and flexibility, permitting developers to adjust and upgrade designs according to needs. The modular design allows for easy integration of new technologies during the development process.
• Simplified Hardware and Software Development: SoMs provide a friendly design environment for both hardware and software developers, avoiding the challenge of building complex PCBs from scratch and allowing them to focus on product-specific functions.
• Easy Integration of Advanced Technologies: Developers can easily integrate AI models and other advanced technologies on SoMs to meet new application demands.
• Reduced Complexity: By integrating multiple system functions, SoMs reduce design complexity, allowing developers to deploy multiple applications using a single carrier board.

These advantages make SoMs widely used across various industries, including IoT, industrial automation, medical devices, and edge computing, among others.