|
|
|
| Construction of Measurement System for Artificial Intelligence Core Technology Innovation Capability:From the Perspective of Innovation Ecosystem |
| Yuan Ye,Wang Shuyue,Tao Yuxiang |
| (School of Economics and Management,Chongqing University of Posts and Telecommunications,Chongqing 400065,China) |
|
|
|
|
Abstract Breaking through key core technologies is an important issue that China faces in building a strong country in science and technology during the "14th Five-Year Plan" period. Artificial intelligence as a core strength of technological change, scientific evaluation of its technical innovation ability, has great significance for Chinese scientific and technological competitiveness. Based on the perspective of the innovation ecosystem, this paper measures the innovation capability of Chinese key core technologies of artificial intelligence from the three dimensions of innovation subject, innovation environment and system benefits. The study found that Chinese key core technology innovation capabilities for artificial intelligence have been increasing year by year, with the number of innovative entities, corporate R&D funds, and algorithm foundation becoming the main influencing factors. Among them, the number of innovation subjects has a higher impact on key core technology innovation capabilities than resource input. At the same time, basic research plays a pivotal role in the process of core technology innovation. Finally, algorithms, data, and computing power are the three significant influencing factors that enhance the key core technologies of artificial intelligence, and these are closely related to the technology life cycle. China should adhere to the innovation orientation, cultivate diversified innovation subjects, continue to encourage algorithmic research, accelerate the construction of open platforms and the formulation of technical standards, coordinate the relationship between technological development and governance, and achieve breakthroughs in key core technologies.
|
|
Received: 06 February 2021
|
|
|
|
|
|
| [1] 封伟毅,李建华,赵树宽.技术创新对高技术产业竞争力的影响——基于中国1995-2010年数据的实证分析[J].中国软科学,2012,27(9):154-164.[2] FRISHAMMAR J, ERICSSON K, PATEL P C. The dark side of knowledge transfer: exploring knowledge leakage in joint R&D projects[J]. Technovation, 2015, 41: 75-88.[3] 陈劲,阳镇,朱子钦.“十四五”时期“卡脖子”技术的破解:识别框架、战略转向与突破路径[J].改革,2020,37(12):5-15.[4] STIFTUNG B. Bertelsmann stiftung's transformation Index (BTI) 2014 — Laos country report[J]. Bertelsmann Stiftung, 2014.[5] 余江,陈凤,张越,等.铸造强国重器:关键核心技术突破的规律探索与体系构建[J].中国科学院院刊,2019,34(3):339-343.[6] 王海军.关键核心技术创新的理论探究及中国情景下的突破路径[J/OL].当代经济管理:1-9[2020-12-20].http://kns.cnki.net/kcms/detail/13.1356.F.20201120.1410.002.html.[7] 新华社.习近平出席中国科学院第十九次院士大会、中国工程院第十四次院士大会开幕会并发表重要讲话[EB/OL]. [2018-05-28]. http://www.gov.cn/xinwen/2018-05/28/content_5294268.htm.[8] 李显君,熊昱,冯堃.中国高铁产业核心技术突破路径与机制[J].科研管理,2020,41(10):1-10.[9] CANNICE M V, CHEN R R, DANIELS J D. Managing international technology transfer risk:alternatives and complements to ownership structure[J].Management International Review, 2004, 44 (1) :129-152.[10] KALE P, SINGH H, PERLMUTTER H. Learning and protection of proprietary assets in strategic alliances: building relational capital[J].Strategic Management Journal,2000,21(3):217-237.[11] 张杰.中国关键核心技术创新的特征、阻碍和突破[J].江苏行政学院学报,2019,19(2):43-52.[12] 张杰,吴书凤.“十四五”时期中国关键核心技术创新的障碍与突破路径分析[J].人文杂志,2021,65(1):9-19.[13] 张治河,苗欣苑.“卡脖子”关键核心技术的甄选机制研究[J].陕西师范大学学报(哲学社会科学版),2020,49(6):5-15.[14] 邵必林,赵煜,宋丹,等.AI产业技术创新系统运行机制与优化对策研究[J].科技进步与对策,2018,35(22):71-78.[15] 房超,李正风,薛颖,等.基于比较分析的人工智能技术创新路径研究[J].中国工程科学,2020,22(4):147-153.[16] 李修全.当前人工智能技术创新特征和演进趋势[J].智能系统学报,2020,15(2):409-412.[17] 黄鲁成,薛爽.机器学习技术发展现状与国际竞争分析[J].现代情报,2019,39(10):165-176.[18] 王友发,张茗源,罗建强,等.专利视角下人工智能领域技术机会分析[J].科技进步与对策,2020,37(4):19-26.[19] MORTAZAVI RAVARI S S, MEHRABANFAR E, BANAITIS A, te al. Framework for assessing technological innovation capability in research and technology organizations[J].Journal of Business Economics and Management,2016,17(6):825-847.[20] CHEN Q, WANG C H, HUANG S Z. Effects of organizational innovation and technological innovation capabilities on firm performance: evidence from rms in China's Pearl River Delta[J].Asia Pacic Business Review,2019,26(1):1-25.[21] ADLER P S, SHENHAR A. Adapting your technolical base: the organi-zational challenge[J]. Sloan Management Review,1990,32(1).[22] YAM R, GUAN J, PUN K, et al. An audit of technological innovation capabilities in Chinese rms: Some empirical ndings in Beijing, China[J].Research Policy,2004,33(8):1123-1140.[23] 吴友军.产业技术创新能力评价指标体系研究[J].商业研究,2004,47(11):27-29.[24] FANG S, XUE X, YIN G, et al. Evaluation and improvement of technological innovation efficiency of new energy vehicle enterprises in China based on dea-tobit model[J].Sustainability,2020,12(18):7509.[25] 梅亮,陈劲,刘洋.创新生态系统:源起、知识演进和理论框架[J].科学学研究,2014,32(12):1771-1780.[26] 吴彤.技术生态学的若干问题[J].科学管理研究,1994(4):55-59.[27] 潘苏楠,李北伟,聂洪光.我国新能源汽车产业可持续发展综合评价及制约因素分析——基于创新生态系统视角[J].科技管理研究,2019,39(22):41-47.[28] 彭中文,何新城.湖南装备制造业技术创新绩效及其竞争力研究[J].湘潭大学学报(哲学社会科学版),2009,33(2):39-43.[29] 刘军.整体网分析讲义:UCINET软件实用指南[M].上海:上海人民出版社,2009.[30] 邓一华,吴贵生.技术创新活动的几种测度方法综述[J].科技进步与对策,2002,19(7):66-67.[31] 王宏起,刘梦,武川,等.区域战略性新兴产业创新生态系统稳定水平评价研究[J].科技进步与对策,2020,37(12):118-125.[32] 吴贵生,王毅,王瑛.政府在区域技术创新体系建设中的作用——以北京区域技术创新体系为例[J].中国科技论坛,2002,18(1):32-37.[33] 张春博,丁堃,贾龙飞.国际人工智能领域计量与可视化研究——基于AAAI年会论文的分析[J].图书情报工作,2012,56(22):69-76.[34] 李旭辉,张胜宝,程刚,等.三大支撑带人工智能产业自主创新能力测度分析[J].数量经济技术经济研究,2020,37(4):3-25.[35] HWANG C L,YOON K.Multiple attribute decision making:methods and applications[M].Springer,Heidelberg,1987.[36] 马宗国,曹璐.制造企业高质量发展评价体系构建与测度——2015—2018年1881家上市公司数据分析[J].科技进步与对策,2020,37(17):126-133.[37] 夏文飞,苏屹,支鹏飞.基于组合赋权法的高新技术企业创新能力评价研究[J].东南学术,2020,33(3):153-161.[38] BARROS C P, LIANG Q B, PEYPOCH N. The technical efficiency of US airlines[J].Transportation Research Part A Policy & Practice,2013,50(2):139-148.[39] 刘红波,林彬.人工智能政策扩散的机制与路径研究——一个类型学的分析视角[J].中国行政管理,2019,35(4):38-45.[40] 黎文靖,郑曼妮.实质性创新还是策略性创新——宏观产业政策对微观企业创新的影响[J].经济研究,2016,51(4):60-73. |
|
|
|
