全球教育機器人市場規模：依機器人類型、應用、地區、範圍及預測

教育機器人市場規模及預測

2024年教育機器人市場規模為14.1269億美元，預計2031年將達45.7735億美元，2024年至2031年複合年增長率為15.83%。教育機器人技術是一個專門領域，旨在從小向學生傳授機器人技術和程式設計原理。我們提供適合不同教育程度、不同複雜程度和學習目標的適合年齡的機器人。在幼兒教育和小學教育中，教育機器人為學生提供了建構和編程能夠執行任務的機器人的工具，促進了實踐學習體驗。這些機器人的設計易於使用和理解，幫助孩子培養 STEM 學科（科學、技術、工程和數學）的基本技能，同時提高學習動機和創造力。中學和大學可以使用更先進和複雜的教育機器人，但這些機器人往往很昂貴。這些機器人專為課題學生更複雜的程式設計任務和專案而設計，符合強調實際應用而非理論學習的高級 STEM 教育課程。

教育機器人對於優先考慮體驗式學習和解決問題技能的 STEM 教育框架至關重要。

透過與機器人一起工作，學生不僅可以學習與機器人和程式設計相關的技術技能，還可以培養重要的認知技能，例如邏輯推理、分析思維和團隊合作。

教育機器人市場提供了各種各樣的產品，旨在滿足不同教育環境和學習目標的需求。

流行的教育機器人包括可編程套件、人形機器人以及整合編碼和機器人教育軟體的專用平台。這些機器人的選擇是基於其教育價值、易用性、可程式性以及與課程標準的兼容性。

隨著全球對 STEM 教育的需求持續增長，教育機器人在幫助學生為技術驅動行業的未來職業做好準備方面發揮著至關重要的作用。

機器人技術的創新，加上對教育改革和數位學習工具的投資增加，預計將進一步推動教育機器人在世界各地教室和學習環境中的成長和採用。

全球教育機器人市場動態

塑造全球教育機器人市場的主要市場動態是：

主要市場推動因素

重視STEM教育：

在全球範圍內，人們越來越重視 STEM 教育，幫助學生為機器人、程式設計和工程等高需求行業的工作做好準備。教育機器人作為互動教材，提升學生對STEM學科的興趣，培養批判性思考、創造力和解決問題的能力。

教育科技解決方案的成長：

數位學習工具、互動式內容和個人化學習平台的進步正在推動教育科技 (EdTech) 解決方案在教室和學習環境中的採用。教育機器人透過提供沉浸式和互動式學習體驗來適應不同學生的學習偏好和風格，從而增強傳統教學方法。

促進包容性教育：

教育機器人有潛力透過滿足具有不同學習能力的學生（包括殘疾學生和特殊教育需求學生）的多樣化需求來支持包容性教育計劃。機器人可以根據個人的學習偏好客製化互動和教學方法，為具有不同認知和身體能力的學習者提供個人化支持。

所需的程式設計和編碼技能：

在數位時代，編碼和程式設計技能變得越來越重要。因此，對能夠從小向兒童介紹計算思維和編碼原理的教育工具的需求不斷增長。教育機器人配備了軟體開發平台和程式設計接口，使學習編碼成為一種引人入勝的互動體驗，並激發人們對電腦科學及相關領域的興趣。

融入學校課程：

教育機器人越來越多地被納入從小學到高等教育機構的各個教育級別的課程和計畫中。政府、教育機構和政策制定者正在認識到將機器人技術和 STEM 教育納入正式學習環境的重要性，以使學生掌握未來勞動力需求所需的技能和知識。

強調 21 世紀技能：

重點正在轉向培養 21 世紀的技能，例如協作、溝通、創造力和解決問題的技能，而不僅僅是學術知識。教育機器人透過協作專案、團隊建立活動和模擬現實場景的動手解決問題練習，促進這些技能的獲得。

機器人技術發展：

機器人技術（包括感測器、執行器、人工智慧 (AI) 和機器學習演算法）的不斷進步，正在催生更複雜和多功能的教育機器人。現代教育機器人提供自主導航、自適應行為和人機互動等增強功能，為學生提供更具吸引力的學習體驗。

家長和老師的要求：

教育利害關係人，包括家長、教師和教育工作者，認識到教育機器人可以幫助提高學生的積極性、參與度和學習成果。隨著利害關係人尋求為學生提供尖端的沉浸式學習體驗，這種認識正在推動教育機構、課外計畫和家庭學習環境對教育機器人的需求。

主要課題

初期投資成本高：

與教育機器人相關的硬體、軟體和培訓通常需要花費大量資金。對於教育機構來說，購買機器人、感測器、程式設計工具和教育內容可能太昂貴，尤其是那些預算緊張和財務拮据的教育機構。

整合和部署複雜性：

將教育機器人融入現有課程和課堂活動既困難又耗時。教師需要專業發展和培訓才能有效地將機器人融入課堂，這可能會導致實施問題和變革阻力。此外，學校和教育工作者在確保與當前教育系統和基礎設施的兼容性方面可能會遇到技術困難。

缺乏教師支援和培訓：

許多教師缺乏將教育機器人帶入課堂所需的知識、技能和資源。資源、技術支援和專業發展機會不足可能會阻礙教育工作者將機器人技術融入他們的教學方法並最大化學生的學習。

有限的課程和教育標準：

將教育機器人納入正式的教育環境可能會對課程調整和教育標準造成課題。為了讓機器人活動得到教育工作者的接受和支持，它們必須與學習目標、學術標準和評估標準保持一致。然而，機器人產業技術進步的快速步伐可能會導致機器人課程材料和評估系統的開發延遲。

耐用性和維護問題：

教育機器人需要持續維護、更新和技術支持，以確保最佳性能和使用壽命。對於教育機構來說，取得機器人配件、軟體和硬體的持續維護和維修所需的資金可能很困難。對機器人專案的可持續性以及更新舊設備或過時設備的成本的擔憂可能會阻礙對教育機器人的長期投資。

可訪問性和公平性問題：

不同學校、地區和地區獲得教育機器人和機器人專案的機會可能並不相同。社會經濟劣勢、數位落差和地理限制可能加劇教育不平等，並限制服務不足群體接受機器人教育的機會。需要有針對性地努力克服無障礙障礙，促進包容性，並確保所有學生都有平等的機會獲得機器人教育機會。

隱私和資料安全風險：

教育機器人可以收集和儲存有關學生的敏感信息，例如行為模式、學習進度和個人數據。關於資料收集、儲存和共享方式的隱私問題可能會給教育機構和機器人開發商帶來道德和法律課題。保護學生隱私和資料安全對於維持信任和遵守隱私法規至關重要。

對教育價值和有效性的看法：

雖然教育機器人可以提高學生的創造力、學習動力和解決問題的能力，但人們對其教育價值和有效性表示懷疑。對過度依賴技術、替代傳統教學方法以及對社交和情感學習的影響的擔憂可能會限制機器人技術在教育中的採用。

主要趨勢

更多採用電子學習和 STEM 教育：

由於其互動性和吸引力，教育機器人越來越多地被納入電子學習環境和 STEM 教育計畫中。這些機器人提供體驗式學習，可以加深學生對科學、技術、工程和數學 (STEM) 等複雜學科的理解。

教育自動化的進步：

學校開始將機器人作為教學助理和教學工具，可以個人化和增強學習體驗。這些機器人可以適應每個學生的需求並提供量身定制的支持，從而創造更具互動性和吸引力的教育環境。

政府與非政府組織投資：

政府和非政府組織（NGO）在教育領域的投資呈現成長趨勢，特別是技術整合。這些投資正在推動教育機器人的採用，教育機器人被視為教育現代化和改善學習成果的寶貴工具。

強調 21 世紀技能：

教育機器人有助於培養 21 世紀的重要技能，例如批判性思維、解決問題、創造力和協作。這些技能在就業市場上越來越受到重視，而教育機器人則提供了一種親身實踐的方式來獲得這些技能，並幫助學生為他們未來的職業生涯做好準備。

產品研發與創新：

教育機器人市場取得了長足的進步，重點是為不同年齡層和教育程度開發複雜且易於使用的機器人。重點是開發具有物件辨識、語音互動和即時編程等先進功能的機器人。這些功能使教育機器人成為更具互動性和更有效的學習工具。

目錄

第1章簡介

• 市場定義
• 市場細分
• 調查方法

第 2 章執行摘要

• 主要發現
• 市場概況
• 市集亮點

第3章市場概況

• 市場規模和成長潛力
• 市場趨勢
• 市場驅動力
• 市場制約因素
• 市場機會
• 波特五力分析

第4章教育機器人市場：依機器人類型

• 人形機器人
• 可程式機器人
• 遙控機器人
• DIY機器人
• 特種機器人

第5章教育機器人市場：依應用分類

• STEM教育
• 編碼教育
• 機器人大賽
• 蒸氣教育
• 工作訓練

第6章教育機器人市場：依最終用戶分類

• 小學和國中
• 高等教育機構
• 機器人社和課外活動
• 父母和家庭使用
• 其他

第7章區域分析

• 北美
• 美國
• 加拿大
• 墨西哥
• 歐洲
• 英國
• 德國
• 法國
• 義大利
• 亞太地區
• 中國
• 日本
• 印度
• 澳洲
• 拉丁美洲
• 巴西
• 阿根廷
• 智利
• 中東/非洲
• 南非
• 沙烏地阿拉伯
• 阿拉伯聯合酋長國

第8章市場動態

• 市場驅動力
• 市場制約因素
• 市場機會
• COVID-19 的市場影響

第9章 競爭格局

• 大公司
• 市場佔有率分析

第10章 公司簡介

• SoftBank Robotics Group
• Wonder Workshop
• LEGO Systems A/S
• Sphero Inc.
• VEX Robotics Inc.
• ROBOTIS Inc.
• Makeblock
• Modular Robotics（including Cubelets）
• Blue Frog Robotics
• Pitsco Education LLC.
• Thames & Kosmos
• WowWee Group Ltd.
• Artec Co. Ltd.
• Ozo EDU Inc.
• RM Educational Resources Ltd.（TTS）
• Learning Resources
• Educational Insights
• Dobot

第11章市場前景與機遇

• 新興技術
• 未來市場趨勢
• 投資機會

第12章附錄

• 縮寫表
• 來源和參考文獻

Educational Robot Market Size And Forecast

Educational Robot Market size was valued at USD 1412.69 Million in 2024 and is projected to reach USD 4577.35 Million by 2031 , growing at a CAGR of 15.83% from 2024 to 2031. Educational robotics, also known as pedagogical robotics, is a specialized field aimed at introducing students to the principles of robotics and programming from an early age. It spans across different educational levels, offering age-appropriate robots that cater to varying levels of complexity and learning objectives. In infant and primary education, educational robotics provides tools for students to build and program robots capable of performing tasks, fostering hands-on learning experiences. These robots are designed to be easy to use and understand, encouraging engagement and creativity while developing foundational skills in STEM subjects (Science, Technology, Engineering, and Mathematics). For secondary and higher education levels, more advanced and sophisticated educational robots are available, although these tend to be more costly. These robots are tailored to challenge students with more complex programming tasks and projects, aligning with advanced STEM education curricula that emphasize practical application over theoretical learning.

Educational robotics is integral to STEM education frameworks, which prioritize experiential learning and problem-solving skills.

By engaging with robots, students not only learn technical skills related to robotics and programming but also develop critical cognitive abilities such as logical reasoning, analytical thinking, and teamwork.

The market for educational robots offers a diverse range of products designed to meet the needs of various educational environments and learning objectives.

Popular educational robots include programmable kits, humanoid robots, and specialized platforms that integrate software for coding and robotics education. These robots are chosen based on their educational value, ease of use, programmability, and compatibility with curriculum standards.

As the demand for STEM education continues to grow globally, educational robotics plays a crucial role in preparing students for future careers in technology-driven industries.

Innovations in robotics technology, coupled with increasing investments in educational reforms and digital learning tools, are expected to further propel the growth and adoption of educational robots in classrooms and learning environments worldwide.

Global Educational Robot Market Dynamics

The key market dynamics that are shaping the global educational robot market include:

Key Market Drivers

Stress on STEM Education:

Globally, there is a growing emphasis on STEM education, aimed at preparing students for careers in high-demand industries such as robotics, programming, and engineering. Educational robots are used as interactive teaching tools to engage students in STEM subjects, fostering critical thinking, creativity, and problem-solving skills.

Growth of EdTech Solutions:

Advances in digital learning tools, interactive content, and personalized learning platforms are driving the adoption of educational technology (EdTech) solutions in classrooms and learning environments. Educational robots enhance traditional teaching methods by providing immersive, interactive learning experiences that cater to diverse student learning preferences and styles.

Promote Inclusive Education:

Educational robots have the potential to support inclusive education programs by addressing the varied needs of students with different learning abilities, including those with disabilities or special educational needs. Robots can tailor their interactions and instructional methods to accommodate individual learning preferences, offering personalized support to learners with diverse cognitive or physical abilities.

Demand for Programming and Coding Skills:

In the digital age, coding and programming skills are increasingly important. Consequently, there is a growing demand for educational tools that introduce children to computational thinking and coding principles early on. Educational robots, equipped with software development platforms and programming interfaces, make learning to code an engaging and interactive experience, sparking interest in computer science and related fields.

Integration into School Curriculum:

Educational robots are being increasingly integrated into curricula and programs at all educational levels, from elementary schools to higher education institutions. Governments, educational institutions, and policymakers recognize the importance of incorporating robotics and STEM education into formal learning environments to equip students with the skills and knowledge necessary for future workforce demands.

Emphasis on 21st-Century Skills:

The focus is shifting towards developing 21st-century skills such as collaboration, communication, creativity, and problem-solving, in addition to academic knowledge. Educational robots facilitate the acquisition of these skills through collaborative projects, team-building activities, and hands-on problem-solving exercises that simulate real-world scenarios.

Developments in Robotics Technology:

Ongoing advancements in robotics technology, including sensors, actuators, artificial intelligence (AI), and machine learning algorithms, are leading to the creation of more sophisticated and versatile educational robots. Modern educational robots offer enhanced capabilities for autonomous navigation, adaptive behavior, and human-robot interaction, providing students with more engaging learning experiences.

Demand from Parents and Teachers:

Educational stakeholders, including parents, teachers, and educators, recognize the benefits of educational robots in boosting student motivation, engagement, and learning outcomes. This recognition is driving an increasing demand for educational robots from educational institutions, after-school programs, and home learning environments, as stakeholders seek to provide students with cutting-edge and immersive learning experiences.

Key Challenges

High Initial Investment Costs:

The hardware, software, and training expenses associated with educational robots are often substantial. Purchasing robots, sensors, programming tools, and instructional content can be prohibitively expensive for some educational institutions, particularly those with tight budgets or financial constraints.

Complexity of Integration and Implementation:

Integrating educational robots into existing curricula and classroom activities can be challenging and time-consuming. Teachers may require professional development and training to effectively incorporate robotics into their lessons, potentially leading to implementation issues and resistance to change. Additionally, schools and educators may encounter technical difficulties in ensuring compatibility with current educational systems and infrastructure.

Lack of Support and Training for Teachers:

Many teachers lack the knowledge, skills, and resources necessary to deploy educational robots in the classroom. Insufficient access to resources, technical support, and professional development opportunities can hinder educators' ability to integrate robotics into their teaching methods and maximize the learning benefits for students.

Limited Curriculum Alignment and Educational Standards:

Integrating educational robots into formal education settings can pose challenges related to curriculum alignment and educational standards. For robotics activities to be accepted and supported by educational stakeholders, they must align with learning objectives, academic standards, and assessment criteria. However, the rapid pace of technological advancement in the robotics industry may cause delays in the development of robot-compatible curriculum materials and evaluation systems.

Durability and Upkeep Concerns:

Educational robots require ongoing maintenance, updates, and technical support to ensure optimal performance and longevity. Securing the necessary funding for continuous upkeep and repairs of robot accessories, software, and hardware can be difficult for educational institutions. Concerns about the sustainability of robotics programs and the cost of updating outdated or obsolete equipment may hinder long-term investments in educational robots.

Accessibility and Equity Issues:

Access to educational robots and robotics programs may not be equal across different schools, districts, and communities. Socioeconomic disadvantages, digital divides, and geographic constraints can exacerbate educational inequalities, limiting access to robotics education for underserved groups. Targeted initiatives are needed to overcome accessibility barriers and promote inclusivity, ensuring all students have equitable access to educational robotics opportunities.

Risks to Privacy and Data Security:

Educational robots may collect and store sensitive information about students, such as behavioral patterns, learning progress, and personal data. Privacy concerns regarding data collection, storage, and sharing practices can present ethical and legal challenges for educational institutions and robot developers. Protecting student privacy and data security is crucial for maintaining trust and compliance with privacy regulations.

Perceived Educational Worth and Efficacy:

While educational robots can enhance student creativity, engagement, and problem-solving skills, there may be skepticism about their perceived educational value and effectiveness. Concerns about over-reliance on technology, the replacement of traditional teaching methods, and the impact on social-emotional learning could limit the adoption of robotics in education.

Key Trends

Rising Adoption of E-learning and STEM Education:

Educational robots are increasingly being integrated into e-learning environments and STEM education programs due to their interactive and engaging nature. These robots offer hands-on learning experiences that can enhance students' understanding of complex subjects such as Science, Technology, Engineering, and Mathematics (STEM).

Increasing Automation in Education:

Schools are beginning to incorporate robots as teaching assistants or instructional tools, which can personalize and enhance the learning experience. These robots can adapt to individual student needs, providing tailored support and fostering a more interactive and engaging educational environment.

Government and NGO Investments:

The growing trend of investments by governments and non-governmental organizations (NGOs) in the education sector, particularly in the integration of technology. These investments are driving the adoption of educational robots, as they are seen as valuable tools in modernizing education and improving learning outcomes.

Focus on 21st Century Skills:

Educational robots are instrumental in developing critical 21st-century skills such as critical thinking, problem-solving, creativity, and collaboration. These skills are increasingly valued in the job market, and educational robots provide practical, hands-on ways to develop them, preparing students for future careers.

Product Development and Innovation:

The market for educational robots is witnessing significant advancements, with a focus on creating sophisticated and user-friendly robots that cater to different age groups and educational levels. There is a notable emphasis on developing robots with advanced capabilities such as object recognition, voice interaction, and real-time programming. These features make educational robots more interactive and effective learning tools.

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Global Educational Robot Market Regional Analysis

Here is a more detailed regional analysis of the global educational robot market:

Asia Pacific

Asia Pacific is substantially dominating the Global Educational Robot Market and is expected to continue its dominance throughout the forecast period.

In the region, the educational robot industry is thriving alongside a growing enthusiasm for sports. Government initiatives aimed at enhancing educational standards are expected to accelerate the integration of educational robots into classrooms.

Moreover, local companies' steadfast dedication to advancing robotics technology acts as a significant driver for the adoption of educational robots in educational curricula. South Korea and Japan stand out as leaders in innovation, contributing significantly to the development of diverse types of robots.

In China, the expanding demand for home-based education is reshaping the educational landscape and driving the expansion of the intelligent education hardware market. As sales of intelligent education products surge, major education technology companies based in China are leading the charge by introducing cutting-edge technologies designed to cultivate students' independent learning skills.

This commitment to innovation underscores China's strategic focus on harnessing technology to transform education, equipping students with essential skills to thrive in an increasingly dynamic global environment.

As economies in the Asia Pacific continue to develop, disposable incomes are rising among families. This financial growth enables parents to invest more in their children's education, including educational technologies like robots.

This trend further accelerates the adoption of educational robots in both formal educational institutions and informal learning environments, such as homes and after-school programs.

Moreover, there is a growing recognition of the importance of early STEM education in the region. Educational robots are uniquely positioned as engaging tools for introducing STEM concepts to young children during their formative years in ECE.

By promoting hands-on learning experiences and interactive engagement, educational robots foster curiosity, creativity, and problem-solving skills from an early age, laying a strong foundation for future academic success and career readiness in technology-driven industries.

Europe

Europe is anticipated to witness the fastest growth in the Global Educational Robot Market during the forecast period. Technological advancements in Europe have cultivated a robust landscape for educational robots, driven by the region's prominent robotics companies and a dedicated focus on innovation.

This environment encourages the development of sophisticated yet cost-effective educational robots tailored to meet regional market demands. These robots are designed not only to enhance learning experiences but also to align with educational standards and curriculum requirements across European countries.

Rising disposable incomes across Europe's developing economies have also played a significant role in the growth of the educational robot market. With increasing financial capabilities, parents are more inclined to invest in their children's education, including adopting educational technologies like robots.

This trend supports the broader integration of innovative teaching tools into educational settings, aiming to enrich learning outcomes and prepare students for future challenges in technology-driven industries.

Moreover, there is a growing recognition of the importance of early childhood education (ECE) in Europe. Educational robots are increasingly seen as valuable tools for introducing STEM (Science, Technology, Engineering, and Mathematics) concepts to young children.

By engaging them in interactive and hands-on learning experiences, these robots help foster critical thinking, problem-solving skills, and creativity from an early age. This focus on ECE aligns with educational goals to nurture a generation of students equipped with essential skills for the future workforce.

Global Educational Robot Market: Segmentation Analysis

The Global Educational Robot Market is segmented based on Robot Type, Application, And Geography.

Educational Robot Market, By Robot Type

• Humanoid Robots
• Programmable Robots
• Remote-Controlled Robots
• Non-Humanoid Robots
• Specialized Robots

Based on Robot Type, the Global Educational Robot Market is bifurcated into Humanoid Robots, Programmable Robots, Remote-Controlled Robots, Non-Humanoid Robots, and Specialized Robots. The Non-Humanoid Robots segment is showing significant growth in the Global Educational Robot Market owing to the increasing adoption of smart devices that simulate actions, recognize faces, and interact with children, thereby enhancing basic learning experiences. Market dynamics are further propelled by ongoing innovations aimed at delivering advanced learning and creative solutions. Also, the increasing popularity of non-humanoid robots thanks to their affordability compared to humanoid counterparts. This cost-effectiveness makes them more accessible to educational institutions operating under budget constraints, facilitating broader adoption across classrooms and educational settings. As a result, the non-humanoid segment continues to expand rapidly, driven by its ability to meet diverse educational needs effectively while offering robust learning opportunities through innovative technological advancements.

Educational Robot Market, By Application

• Primary Education
• Secondary Education
• Special Education

Based on Application, the Global Educational Robot Market is bifurcated into Primary Education, Secondary Education, and Special Education. The Higher Education segment is showing significant growth in the Global Educational Robot Market driven by the growing demand for robots extends into research and development projects focused on real-world applications. This trend is particularly evident in higher education institutions, which frequently collaborate with industry partners to enrich their curriculum and prepare students for professional careers. Educational robots play a pivotal role in facilitating these collaborations by serving as a platform for industry professionals to contribute to course content, provide internship opportunities, and participate in joint research initiatives. This dynamic interaction between academia and industry is anticipated to significantly bolster the growth of the educational robotics segment, ensuring that graduates acquire practical skills and knowledge aligned with current industry needs and technological advancements.

Educational Robot Market, By Geography

• North America
• Europe
• Asia Pacific
• Rest of the World

Based on Geography, the Global Educational Robot Market is classified into North America, Europe, Asia Pacific, and the Rest of the World. Asia Pacific is substantially dominating the Global Educational Robot Market and is expected to continue its dominance throughout the forecast period. In the region, the educational robot industry is thriving alongside a growing enthusiasm for sports. Government initiatives aimed at enhancing educational standards are expected to accelerate the integration of educational robots into classrooms. Moreover, local companies' steadfast dedication to advancing robotics technology acts as a significant driver for the adoption of educational robots in educational curricula. South Korea and Japan stand out as leaders in innovation, contributing significantly to the development of diverse types of robots. In China, the expanding demand for home-based education is reshaping the educational landscape and driving the expansion of the intelligent education hardware market. As sales of intelligent education products surge, major education technology companies based in China are leading the charge by introducing cutting-edge technologies designed to cultivate students' independent learning skills.

Key Players

• The "Global Educational Robot Market" study report will provide valuable insight with an emphasis on the global market including some of the major players such as
• SoftBank Robotics Group, Wonder Workshop, LEGO Systems A/S, Sphero, Inc., VEX Robotics, Inc., ROBOTIS, Inc., Makeblock, Modular Robotics (including Cubelets), Blue Frog Robotics, Pitsco Education LLC., Thames & Kosmos, WowWee Group Ltd., Artec Co. Ltd., Ozo EDU, Inc., RM Educational Resources Ltd. (TTS), Learning Resources, Educational Insights, Dobot.

Our market analysis also entails a section solely dedicated to such major players wherein our analysts provide an insight into the financial statements of all the major players, along with product benchmarking and SWOT analysis. The competitive landscape section also includes key development strategies, market share, and market ranking analysis of the above-mentioned players globally.

• Global Educational Robot Market Recent Developments
• In April 2023, Dobot announced the opening of a branch in Tokyo, Japan. The goal of this expansion is to give local customers and the Japanese market with a comprehensive spectrum of accelerated automation adoption.
• In March 2023, LEGO Education will release Hannah's STEAM Heroes A Career Toolkit, a free classroom resource to help teachers motivate their children as they pursue STEAM careers.
• In March 2023, Makeblock announced a partnership with Douglas Stewart Company (DSC), a North American distributor focused on education. This collaboration sought to offer Makeblock's engaging and hands-on STEM solutions to North American schools to teach robotics and coding.
• In January 2023, ABB Robotics announced the collaboration with premier universities to reduce the skills gap in robotic education. The agreements with Ho Chi Minh City (HCMC) University of Technology, Hanoi University of Technology, Da Nang University of Technology, HCMC International University, and Hanoi University of Industry include the provision of a training facility for each institution, complete with robots and simulation software.
• In July 2023, ABB Robotics announced the launch of comprehensive robot training to prepare students for the future of work. The package includes an easy-to-use GoFa collaborative robot cell, 56 hours of instructional materials, a globally recognized STEM certification, and the most recent global campaign to collaborate with schools to close the automation skills gap.

TABLE OF CONTENTS

1. Introduction

• Market Definition
• Market Segmentation
• Research Methodology

2. Executive Summary

• Key Findings
• Market Overview
• Market Highlights

3. Market Overview

• Market Size and Growth Potential
• Market Trends
• Market Drivers
• Market Restraints
• Market Opportunities
• Porter's Five Forces Analysis

4. Educational Robot Market, By Robot Type

• Humanoid Robots
• Programmable Robots
• Remote-Controlled Robots
• DIY (Do-It-Yourself) Robots
• Specialized Robots

5. Educational Robot Market, By Application

• STEM Education
• Coding Education
• Robotics Competitions
• STEAM Education
• Vocational Training

6. Educational Robot Market, By End-User

• Primary and Secondary Schools
• Higher Education Institutions
• Robotics Clubs and Extracurricular Programs
• Parental and Home Use
• Others

7. Regional Analysis

• North America
• United States
• Canada
• Mexico
• Europe
• United Kingdom
• Germany
• France
• Italy
• Asia-Pacific
• China
• Japan
• India
• Australia
• Latin America
• Brazil
• Argentina
• Chile
• Middle East and Africa
• South Africa
• Saudi Arabia
• UAE

8. Market Dynamics

• Market Drivers
• Market Restraints
• Market Opportunities
• Impact of COVID-19 on the Market

9. Competitive Landscape

• Key Players
• Market Share Analysis

10. Company Profiles

• SoftBank Robotics Group
• Wonder Workshop
• LEGO Systems A/S
• Sphero Inc.
• VEX Robotics Inc.
• ROBOTIS Inc.
• Makeblock
• Modular Robotics (including Cubelets)
• Blue Frog Robotics
• Pitsco Education LLC.
• Thames & Kosmos
• WowWee Group Ltd.
• Artec Co. Ltd.
• Ozo EDU Inc.
• RM Educational Resources Ltd. (TTS)
• Learning Resources
• Educational Insights
• Dobot

11. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

12. Appendix

• List of Abbreviations
• Sources and References