RISC-V Architecture on MCUs: Strengths, Weaknesses, and the Path Forward

What is RISC-V?

RISC-V (pronounced “risk-five”) is an open standard Instruction Set Architecture (ISA) that was developed at the University of California, Berkeley in 2010. Unlike proprietary ISAs such as ARM or x86, RISC-V is available as an open standard that can be used by anyone without licensing fees or royalties. This makes it particularly attractive for both academic research and commercial applications.

As its name suggests, RISC-V follows the Reduced Instruction Set Computer (RISC) principles, emphasizing a simplified and efficient set of instructions rather than the more complex instruction sets found in CISC (Complex Instruction Set Computer) architectures. The RISC philosophy leads to processors that can be smaller, more energy-efficient, and easier to implement.

What truly sets RISC-V apart from other ISAs is its modular design. It consists of a mandatory base integer ISA (either 32-bit or 64-bit), with optional standard extensions that can be added based on specific application requirements. This allows designers to create processors that are precisely tailored to their needs, including only the necessary functionality and avoiding the overhead of unused features.

RISC-V is maintained by RISC-V International, a non-profit organization with members from across the technology industry, academia, and research institutions. As an open ISA, RISC-V has fostered a collaborative ecosystem where innovations are shared, scrutinized, and improved upon by a global community, accelerating its development and adoption across various computing domains from tiny embedded systems to high-performance computing.

The landscape of microcontroller (MCU) architectures has long been dominated by proprietary solutions, most notably those from ARM. These established architectures, while powerful and widely adopted, often come with licensing fees and restrictions that can hinder innovation and increase costs ¹. In response to these limitations, a new contender has emerged: RISC-V. This article delves into the RISC-V architecture, specifically focusing on its application within microcontrollers. We will explore the fundamental strengths that are driving its increasing adoption, the weaknesses that still need to be addressed, examine its current applications, and compare it with established architectures like ARM Cortex-M.

Understanding the Core Strengths of RISC-V for Microcontrollers

RISC-V stands out due to its foundational principles of being free and open-source. This characteristic alone has profound implications for the microcontroller industry.

Open-Source and Royalty-Free Nature: Democratizing Access and Fostering Innovation

Unlike proprietary instruction set architectures (ISAs), RISC-V is available to anyone to design, manufacture, and sell processor cores without incurring licensing fees or facing legal restrictions ¹. This open access eliminates a significant financial barrier, allowing smaller companies, startups, and academic institutions to engage in hardware innovation without the substantial upfront costs associated with licensing proprietary ISAs. This democratization of processor design can lead to a more diverse and competitive market, potentially accelerating the pace of technological advancement. Furthermore, the open standard encourages collaboration and innovation across the industry ¹. By providing a common, freely accessible foundation, RISC-V fosters a shared knowledge base and promotes collaborative development efforts. This collective approach can lead to more robust and innovative solutions as a wider range of experts contribute their knowledge and perspectives.

Customization and Extensibility: Tailoring Processors for Specific Applications

A significant advantage of RISC-V is its inherent flexibility and extensibility. The RISC-V ISA can be freely extended with custom instructions tailored to the specific needs of an application ¹. This capability allows designers to optimize the power, performance, and area (PPA) of their microcontrollers for their intended use. For instance, specialized instructions can be added to accelerate specific algorithms or improve efficiency for particular tasks. Complementing this is the modular design of RISC-V, which enables the integration of only the necessary features into a microcontroller ¹. This selective inclusion of functionalities reduces the consumption of hardware resources, leading to smaller and more energy-efficient designs, which are particularly valuable for embedded and Internet of Things (IoT) applications. By avoiding the overhead of unnecessary hardware, manufacturers can create MCUs that are precisely tailored for their intended purpose.

flowchart TB
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        subgraph "Standard Extensions"
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            A["A Extension<br>(Atomic Operations)"]
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            D["D Extension<br>(Double-Precision Floating-Point)"]
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Cost-Effectiveness: Lowering Barriers to Entry and Reducing Manufacturing Costs

The absence of licensing fees associated with RISC-V directly translates to lower costs for microcontroller manufacturers ¹. This reduction in overhead can make advanced microcontroller technology more accessible to a broader range of applications and industries, potentially opening up new markets and enabling the use of more sophisticated MCUs in cost-sensitive designs. Furthermore, the open model of RISC-V encourages the pooling of resources and expertise, leading to the sharing of software development costs across multiple companies ¹. This collaborative approach to developing tools and software can reduce the overall financial burden for individual organizations, making it more economically viable to adopt and innovate with RISC-V.

Power Efficiency: Advantages for Battery-Powered and Resource-Constrained Devices

The concise instruction set of RISC-V contributes to higher energy efficiency in microcontrollers ⁸. Simpler instructions generally require fewer clock cycles and less complex hardware to execute, resulting in lower power consumption. This is a critical consideration for battery-operated devices and resource-constrained applications where energy efficiency is paramount. Additionally, the modularity of RISC-V allows designers to exclude power-hungry units when they are not required for a specific application ¹. By tailoring the hardware configuration to the specific needs of the application, significant reductions in power consumption can be achieved. For example, a simple sensor node in an IoT network might not require a floating-point unit, and its exclusion can lead to substantial power savings.

Enhanced Security Features: Open Scrutiny and Customizable Security Extensions

The open-source nature of RISC-V fosters greater transparency, allowing for easier inspection of the architecture and identification of potential vulnerabilities ¹. This public scrutiny can lead to the faster detection and patching of security flaws, enhancing the overall security of RISC-V based microcontrollers. Moreover, the ability to implement custom security features and extensions within the RISC-V ISA provides a significant advantage ¹. This enables developers to tailor security measures to the specific requirements of different applications. For instance, in applications where data security is critical, specialized hardware or instructions can be added to provide enhanced protection against potential threats.

Addressing the Weaknesses and Limitations of RISC-V in MCUs

Despite its numerous strengths, RISC-V is still a relatively young architecture in comparison to established players like ARM, and it faces certain weaknesses and limitations, particularly in the context of microcontrollers.

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    strengths["Strengths"]
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Ecosystem Maturity: Gaps in Software Support, Development Tools, and Middleware

The software ecosystem for RISC-V, while growing rapidly, is still less mature compared to that of established ISAs like ARM ⁹. This relative immaturity can translate to fewer readily available software libraries, operating system ports, and middleware solutions for RISC-V based microcontrollers. Consequently, developers might need to invest more time and effort in developing or porting software, potentially increasing the overall development timeline and cost. Furthermore, the availability of compilers, debuggers, and other essential development tools for RISC-V is still catching up to the level of sophistication and feature richness found in tools supporting more established architectures ⁹. This can impact developer productivity and the efficiency of debugging and optimization processes.

Standardization Challenges: Potential for Fragmentation and Compatibility Issues

While the flexibility of adding extensions is a key strength of RISC-V, it also presents a potential challenge in terms of standardization. The freedom to implement custom instructions can lead to fragmentation within the RISC-V ecosystem, potentially causing compatibility problems between different RISC-V core implementations ⁹. Software written for a specific RISC-V core with certain extensions might not run seamlessly on another core that has different or missing extensions. This lack of universal compatibility could hinder the development of a truly unified software ecosystem for RISC-V. Additionally, there is an ongoing effort to establish clear standards for implementations, tools, and extensions within the RISC-V community ¹⁷. The absence of fully comprehensive and widely adopted standards can create uncertainty for developers and manufacturers, potentially affecting interoperability and slowing down widespread adoption.

Performance Benchmarks: Comparing RISC-V with Established Architectures like ARM Cortex-M

In terms of raw performance, RISC-V might not yet consistently outperform established architectures like ARM Cortex-M across all benchmarks ¹⁰. While RISC-V can be highly optimized for specific tasks through custom extensions, achieving comparable or superior general-purpose performance to the highly refined ARM Cortex-M cores is an ongoing area of development. It is important to note that the performance of a RISC-V based microcontroller can vary significantly depending on the specific core implementation and its configuration ²¹. The wide range of customization options means that performance is heavily influenced by the design choices made, unlike more standardized architectures where performance characteristics are often more predictable.

Hardware Support and Availability: Fewer Options Compared to Mature Ecosystems

The availability of commercial hardware options and development boards for RISC-V based microcontrollers is currently fewer compared to the vast selection available for ARM ⁹. This limited selection can restrict the choices available to developers and potentially increase the cost or difficulty of prototyping and development. A smaller range of off-the-shelf components might necessitate more custom design work, which can add complexity and time to the development process.

Intellectual Property Concerns: Navigating the Open-Source Landscape and Potential Patent Issues

Despite the open-source nature of the base RISC-V ISA, intellectual property (IP) concerns related to specific RISC-V extensions might still arise ⁹. While the core ISA is freely accessible, companies developing proprietary extensions might hold patent rights over their innovations, potentially creating complexities for those wishing to use these extensions in their designs. Furthermore, the verification of RISC-V cores can be a challenging endeavor due to the lack of a single, central design and verification team ¹⁶. Ensuring the functional correctness, safety, and security of the diverse range of RISC-V implementations requires robust and potentially distributed verification efforts across the community and commercial entities.

Real-World Applications of RISC-V Based MCUs

Despite its relative youth, RISC-V has already found its way into a diverse range of real-world applications, demonstrating its versatility and growing maturity.

Internet of Things (IoT) and Wearables

RISC-V’s low power consumption and customization options make it an ideal choice for power-constrained and battery-operated designs commonly found in IoT devices and wearables ¹. For example, the ESP32-C3 microcontroller, based on a RISC-V core, integrates Wi-Fi and Bluetooth capabilities, making it well-suited for sMarchhome devices and wearable applications ⁸. Other examples include the Pinecil sMarchsoldering iron and various True Wireless Stereo (TWS) earphones, which leverage the efficiency and flexibility of RISC-V ²³. The ability to tailor the MCU to the specific sensor or communication needs of an IoT device is a significant advantage driving this adoption.

Industrial Automation

RISC-V based MCUs are also finding applications in industrial automation, such as monitoring environmental parameters and machine status ⁸. The flexibility and potential for cost reduction offered by RISC-V can be particularly beneficial in industrial settings, where customized MCUs optimized for specific control tasks can improve efficiency and reduce overall system costs.

SMarchHomes and Consumer Electronics

Beyond basic IoT devices, RISC-V is being integrated into more complex sMarchhome and consumer electronics. Examples include sMarchplugs, lighting systems, and temperature controllers ⁸. Notably, the Raspberry Pi Pico 2, the successor to the popular RP2040 microcontroller, incorporates RISC-V cores ¹. Furthermore, RISC-V is appearing in everyday consumer products like television controllers and sMarchlamps ²³. This increasing presence in consumer devices indicates a growing confidence in the architecture’s capabilities and cost-effectiveness for high-volume applications.

Automotive

The automotive industry is showing increasing interest in RISC-V for applications such as Advanced Driver-Assistance Systems (ADAS), infotainment systems, and battery management systems ⁹. The ability to customize processors for specific automotive subsystems and the desire for vendor independence are key factors driving this adoption in a sector with stringent performance and safety requirements.

Other Applications

RISC-V’s versatility extends to various other domains. It is already used in storage controllers and camera modules ³. The architecture’s security and reliability features make it suitable for aerospace and government applications ³. Renesas has introduced general-purpose RISC-V MCUs targeting medical devices, small appliances, and industrial systems ²⁵. This broad range of applications highlights the adaptability of the RISC-V architecture across different computing needs.

RISC-V vs. ARM Cortex-M: A Comparative Analysis for MCUs

When considering microcontrollers, ARM’s Cortex-M series is a dominant force. Comparing RISC-V with ARM Cortex-M across several key parameters provides valuable insights for developers and decision-makers.

Feature	RISC-V	ARM Cortex-M
ISA Availability	Open Standard, Royalty-Free	Proprietary, Licensing Fees
Performance	Improving, Customizable for Specific Tasks	Well-Established, Wide Range of Options
Power Consumption	Potentially Lower Due to Modularity	Highly Optimized, Energy-Efficient Focus
Cost	Lower (No Licensing Fees)	Higher (Licensing Fees Apply)
Ecosystem	Rapidly Growing, Less Mature	Mature, Extensive, Well-Supported
Customization	Highly Customizable, Extensible	Limited by Proprietary IP
Security	Open Scrutiny, Customizable Extensions	Established Features, Extensively Tested
Software Support	Growing but Limited	Extensive Libraries and Middleware
Market Adoption	Emerging, Growing Rapidly	Dominant Market Position
Development Tools	Evolving Toolchain	Mature, Industry-Standard Tools

ARM Cortex-M has a long-standing reputation for energy efficiency and performance in embedded systems ¹⁴. RISC-V’s performance is steadily improving and can be competitive, particularly when customized for specific workloads ¹⁰. Both architectures prioritize low power consumption for MCUs ⁴. However, RISC-V’s smaller silicon footprint and modularity have the potential to offer power advantages in certain implementations ⁶. In terms of cost, RISC-V holds a clear advantage due to the absence of licensing fees, which can significantly reduce production costs compared to ARM cores that require licensing ¹.

While ARM boasts a mature and extensive ecosystem with a wide array of tools, software, and support ⁴, RISC-V’s ecosystem is rapidly expanding but still has ground to cover ⁴. Customization is where RISC-V truly shines, offering significantly more flexibility and extensibility compared to the more restricted, proprietary nature of ARM ¹. Both architectures can be used to build secure MCUs, but RISC-V’s open nature allows for greater scrutiny and the implementation of custom security extensions ¹.

The Current State and Future Trends of the RISC-V Ecosystem

The RISC-V ecosystem is experiencing rapid growth and gaining significant traction in the semiconductor industry. The market is projected to grow substantially with high compound annual growth rates (CAGR) over the coming years ². Billions of RISC-V cores have already been shipped, and this number is expected to increase dramatically ². This widespread adoption is supported by a growing community and increasing industry support. RISC-V International boasts a large membership, including major players in the technology sector such as Google, Intel, and Qualcomm ³.

Collaborative efforts like the RISC-V Software Ecosystem (RISE) project are focused on enhancing software support and development tools for the architecture ¹⁶. Advancements in software and tooling are continuously being made, with increasing availability of compilers, system libraries, kernel support (Linux), and language runtimes like Java and Python ¹. The development of simulators, emulators, and comprehensive developer infrastructure is further strengthening the ecosystem ³⁴.

Looking ahead, RISC-V is poised for significant growth in key areas such as artificial intelligence (AI), machine learning, edge computing, and the automotive sector ². Its unique characteristics make it well-suited to the demands of these emerging technologies. Ultimately, RISC-V has the potential to reshape the semiconductor industry by offering a compelling alternative to established architectures ⁹.

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Challenges and Opportunities in Adopting RISC-V MCUs

Adopting RISC-V microcontrollers presents both challenges and significant opportunities for the industry. Overcoming the relative immaturity of the ecosystem through continued investment and community engagement is crucial ⁹. Efforts towards greater standardization are necessary to mitigate the risk of fragmentation and ensure compatibility across different RISC-V implementations ⁹. Building strong partnerships and consistently demonstrating performance competitiveness against established players like ARM will be essential for wider adoption ¹⁰. Furthermore, carefully managing intellectual property concerns and ensuring clarity around licensing for RISC-V extensions will help build trust and encourage innovation ⁹.

Challenges

Challenge	Description	Potential Solutions
Ecosystem Maturity	Limited software libraries, middleware, and development tools compared to established architectures	• Community-driven development • Increased industry investment • Academic collaborations
Standardization	Risk of fragmentation due to customization flexibility and lack of comprehensive standards	• RISC-V International standards development • Industry consensus on core extensions • Compatibility testing frameworks
Performance Benchmarks	Variable performance across implementations, not consistently outperforming ARM	• Targeted optimizations for general workloads • Custom extensions for specific applications • Continued architecture refinement
Hardware Availability	Fewer commercial options and development boards	• More semiconductor companies adopting RISC-V • Greater variety of reference designs • Low-cost development platforms
IP Concerns	Potential ambiguity around custom extensions and patents	• Clear licensing frameworks • Standardized approach to custom extensions • Intellectual property guidelines

Opportunities

Despite these challenges, the opportunities presented by RISC-V are substantial. The increasing demand for customization and specialized processors in rapidly growing fields like AI and IoT provides a fertile ground for RISC-V adoption ¹. The cost savings offered by the royalty-free nature of RISC-V can be leveraged to create more competitive products and open up new markets ¹. The open-source platform fosters innovation through collaborative development and the free exchange of ideas ¹. Finally, for regions seeking to reduce their reliance on foreign intellectual property, RISC-V offers a path towards achieving strategic independence in semiconductor technology ².

Opportunity	Description	Potential Impact
Customization Demand	Growing need for specialized processors in AI, IoT, and edge computing	• Perfect fit for application-specific optimizations • Energy efficiency in constrained environments • Competitive advantage in specialized markets
Cost Reduction	Royalty-free nature offering significant cost savings	• More affordable MCUs for cost-sensitive applications • Higher margins for manufacturers • Expanded market reach
Innovation Platform	Open-source nature encouraging collaborative development	• Faster pace of innovation • Broader range of contributors • Novel architectural approaches
Strategic Independence	Nations and companies seeking semiconductor sovereignty	• Reduced dependence on foreign IP • Regional semiconductor development • Technological self-sufficiency
Emerging Applications	New technologies requiring specialized processing capabilities	• AI/ML acceleration at the edge • Advanced automotive systems • Next-gen IoT networks

Key Success Factors for RISC-V MCU Adoption

Community Engagement: Fostering active participation in ecosystem development
Industry Partnerships: Collaboration between established players and new entrants
Educational Initiatives: Training developers on RISC-V architecture and tools
Reference Implementations: Well-documented, high-quality reference designs
Standards Development: Clear guidelines to ensure compatibility and interoperability

Conclusion: The Future is Open for RISC-V MCUs

The RISC-V architecture presents a compelling alternative in the microcontroller landscape, offering significant strengths in its open-source nature, customization capabilities, cost-effectiveness, power efficiency, and security potential. While challenges remain, particularly in the maturity of its ecosystem and standardization efforts, the rapid growth and increasing adoption of RISC-V indicate a promising future. Its ability to be tailored for specific applications, coupled with the absence of licensing fees, positions it as a disruptive force with the potential to drive innovation and reshape the microcontroller market. As the ecosystem continues to mature and more hardware and software options become available, RISC-V is poised to play an increasingly important role in powering the next generation of embedded systems and beyond. The open revolution in microcontrollers is well underway, and RISC-V is at its forefront.

Reference Works

The RISC-V Architecture: 16 Boards and MCUs You Should Know | Elektor Magazine, access date March27, 2025, https://www.elektormagazine.com/articles/the-risc-v-architecture-16-boards-mcus
The Rise of RISC-V: Is It a Threat to ARM and x86? (Market Growth Stats) | PatentPC, access date March27, 2025, https://patentpc.com/blog/the-rise-of-risc-v-is-it-a-threat-to-arm-and-x86-market-growth-stats
RISC-V – ExplainingComputers.com, access date March27, 2025, https://explainingcomputers.com/riscv.html
What is RISC-V? – How Does it Work? – Synopsys, access date March27, 2025, https://www.synopsys.com/glossary/what-is-risc-v.html
RISC-V Microcontrollers: The Next Big Thing In Embedded Systems? – Pallav Aggarwal, access date March27, 2025, https://pallavaggarwal.in/2023/09/30/risc-v-based-microcontroller/
RISC-V vs ARM: Which Open Standard RISC Architecture Is Better for Your Microchip Project? – DRex Electronics, access date March27, 2025, https://www.icdrex.com/risc-v-vs-arm-which-open-standard-risc-architecture-is-better-for-your-microchip-project/
RISC-V Architecture: A Comprehensive Guide to the Open-Source ISA – Wevolver, access date March27, 2025, https://www.wevolver.com/article/risc-v-architecture
Guide to RISC-V MCU: Comparative Analysis of ESP32-C3, SiFive …, access date March27, 2025, https://www.dfrobot.com/blog-13495.html
RISC-V Processors : The Comprehensive Guide (2024) – Stromasys, access date March27, 2025, https://www.stromasys.com/resources/all-about-the-risc-v-processors/
RISC-V: The Open Revolution, access date March27, 2025, https://rdia.gov.sa/media/imhpqhdn/risc-v-the-open-revolution-v3-1.pdf
How to Get Started with RISC-V-Based Microcontrollers – DigiKey, access date March27, 2025, https://www.digikey.com/en/articles/how-to-get-started-with-risc-v-based-microcontrollers
Arm vs. RISC-V in 2025: Which Architecture Will Lead the Way? – EE Times Europe, access date March27, 2025, https://www.eetimes.eu/arm-vs-risc-v-in-2025-which-architecture-will-lead-the-way/
A Comparative Guide to RISC-V, ARM and x86 #riscv – YouTube, access date March27, 2025, https://www.youtube.com/watch?v=GXBZg_KE8Ac
RISC-V vs. ARM processors: A quick comparison – Fierce Electronics, access date March27, 2025, https://www.fierceelectronics.com/analog/risc-v-vs-arm-processors-quick-comparison
RISC-V vs ARM – A Strategic Guide to Processor Architecture – Stromasys, access date March27, 2025, https://www.stromasys.com/resources/risc-v-vs-arm-processors-comparative-analysis/
RISC-V: The underdog chip poised to reshape the tech landscape – UST, access date March27, 2025, https://www.ust.com/en/insights/risc-v-the-underdog-chip-poised-to-reshape-the-tech-landscape
RISC-V: Navigating Commercial Success and Geopolitical Challenges – FutureBridge, access date March27, 2025, https://www.futurebridge.com/industry/perspectives-mobility/risc-v-navigating-commercial-success-and-geopolitical-challenges/
RISC-V is making moves, but how will it hit the mainstream? – The Register, access date March27, 2025, https://www.theregister.com/2025/01/02/riscv_journey_to_mainstream/
Will RISC-V adoption in automotive challenge traditional paradigms? – N-iX, access date March27, 2025, https://www.n-ix.com/risc-v-adoption-in-automotive/
RISC-V’s Software Portability Challenge – Semiconductor Engineering, access date March27, 2025, https://semiengineering.com/risc-vs-hardware-software-contract/
Arm vs RISC-V? Which One Is The Most Efficient? – YouTube, access date March27, 2025, https://www.youtube.com/watch?v=hdnONr-cXds
Verification Challenges for RISC-V Adoption – GSA – Global Semiconductor Alliance, access date March27, 2025, https://www.gsaglobal.org/forums/verification-challenges-for-risc-v-adoption/
Examples of normal everyday consumer products that are using RISC-V? : r/RISCV – Reddit, access date March27, 2025, https://www.reddit.com/r/RISCV/comments/10m2gi9/examples_of_normal_everyday_consumer_products/
RISC-V Adoption Will Be Accelerated by AI, According to New Omdia Research, access date March27, 2025, https://www.semiconductor-digest.com/risc-v-adoption-will-be-accelerated-by-ai-according-to-new-omdia-research/
Renesas Introduces Industry’s First General-Purpose 32-bit RISC-V MCUs with Internally Developed CPU Core, access date March27, 2025, https://www.renesas.com/en/about/newsroom/renesas-introduces-industry-s-first-general-purpose-32-bit-risc-v-mcus-internally-developed-cpu-core
RISC-V General Purpose MCU Overview – Renesas, access date March27, 2025, https://www.renesas.com/en/video/risc-v-general-purpose-mcu-overview
Exploring the Differences: ARM vs. RISC-V Architecture – DEV Community, access date March27, 2025, https://dev.to/adityapratapbh1/exploring-the-differences-arm-vs-risc-v-architecture-50e1
RISC-V vs ARM: A Comprehensive Comparison of Processor Architectures – Wevolver, access date March27, 2025, https://www.wevolver.com/article/risc-v-vs-arm
RISC Computing: Trends and Market Predictions – Stromasys, access date March27, 2025, https://www.stromasys.com/resources/unlocking-the-future-trends-in-risc-computing/
RISC-V Technology Market Report: Trends, Forecast and Competitive Analysis to 2030, access date March27, 2025, https://www.lucintel.com/risc-v-technology-market.aspx
RISC-V Tech Market Size & Share Analysis – Industry Research Report – Growth Trends, access date March27, 2025, https://www.mordorintelligence.com/industry-reports/risc-v-tech-market
RISC-V Technology Market Size, Share & Growth Analysis Report – BCC Research, access date March27, 2025, https://www.bccresearch.com/market-research/semiconductor-manufacturing/global-risc-v-technology-market.html
What RISC-V Means for the Future of Chip Development – CSIS, access date March27, 2025, https://www.csis.org/analysis/what-risc-v-means-future-chip-development
RISC-V Software: Great Progress in 2024 and Much More Ahead in 2025 – SiFive, access date March27, 2025, https://www.sifive.com/blog/risc-v-software-great-progress-in-2024-and-much-mo
RISC-V: What it is and Why it Matters | Center for Security and Emerging Technology – CSET, access date March27, 2025, https://cset.georgetown.edu/article/risc-v-what-it-is-and-why-it-matters/
RISC-V Unleashes Your Imagination – Renesas, access date March27, 2025, https://www.renesas.com/en/blogs/risc-v-unleashes-your-imagination
RISC-V Microcontroller Hardware Design (CH32V003 PCB Design KiCAD) – YouTube, access date March27, 2025, https://www.youtube.com/watch?v=i5q467s_eZo
Block diagram of RISCV-SoC and its five-stage RISC-V processor…. – ResearchGate, access date March27, 2025, https://www.researchgate.net/figure/Block-diagram-of-RISCV-SoC-and-its-five-stage-RISC-V-processor-Resources-from-different_fig3_363175823
Including the SDK、HDK、Datasheet of RISC-V MCU CH32V307 and other relevant development materials – GitHub, access date March27, 2025, https://github.com/openwch/ch32v307
32-bit general-purpose RISC-V MCU-CH32V003 – NanjingQinhengMicroelectronics – wch, access date March27, 2025, https://www.wch-ic.com/products/CH32V003.html