Executive Yuan Promotes Free Economic Demonstration Zone

Blockchain and General Data Protection Regulation (GDPR) compliance issues (2019) I. Brief 　　Blockchain technology can solve the problem of trust between data demanders and data providers. In other words, in a centralized mode, data demanders can only choose to believe that the centralized platform will not contain the false information. However, in the decentralized mode, data isn’t controlled by one individual group or organization[1], data demanders can directly verify information such as data source, time, and authorization on the blockchain without worrying about the correctness and authenticity of the data. 　　Take the “immutable” for example, it is conflict with the right to erase (also known as the right to be forgotten) in the GDPR.With encryption and one-time pad (OTP) technology, data subjects can make data off-chain storaged or modified at any time in a decentralized platform, so the problem that data on blockchain not meet the GDPR regulation has gradually faded away. II. What is GDPR? 　　The purpose of the EU GDPR is to protect user’s data and to prevent large-scale online platforms or large enterprises from collecting or using user’s data without their permission. Violators will be punished by the EU with up to 20 million Euros (equal to 700 million NT dollars) or 4% of the worldwide annual revenue of the prior financial year. 　　The aim is to promote free movement of personal data within the European Union, while maintaining adequate level of data protection. It is a technology-neutral law, any type of technology which is for processing personal data is applicable. 　　So problem about whether the data on blockchain fits GDPR regulation has raise. Since the blockchain is decentralized, one of the original design goals is to avoid a large amount of centralized data being abused. 　　Blockchain can be divided into permissioned blockchains and permissionless blockchains. The former can also be called “private chains” or “alliance chains” or “enterprise chains”, that means no one can join the blockchain without consent. The latter can also be called “public chains”, which means that anyone can participate on chain without obtaining consent. 　　Sometimes, private chain is not completely decentralized. The demand for the use of blockchain has developed a hybrid of two types of blockchain, called “alliance chain”, which not only maintains the privacy of the private chain, but also maintains the characteristics of public chains. The information on the alliance chain will be open and transparent, and it is in conflict with the application of GDPR. III. How to GDPR apply to blockchain ? 　　First, it should be determined whether the data on the blockchain is personal data protected by GDPR. Second, what is the relationship and respective responsibilities of the data subject, data controller, and data processor? Finally, we discuss the common technical characteristics of blockchain and how it is applicable to GDPR. 1. Data on the blockchain is personal data protected by GDPR? 　　First of all, starting from the technical characteristics of the blockchain, blockchain technology is commonly decentralized, anonymous, immutable, trackable and encrypted. The other five major characteristics are immutability, authenticity, transparency, uniqueness, and collective consensus. 　　Further, the blockchain is an open, decentralized ledger technology that can effectively verify and permanently store transactions between two parties, and can be proved. 　　It is a distributed database, all users on the chain can access to the database and the history record, also can directly verify transaction records. Each nodes use peer-to-peer transmission for upload or transfer information without third-party intermediation, which is the unique “decentralization” feature of the blockchain. 　　In addition, the node or any user on the chain has a unique and identifiable set of more than 30 alphanumeric addresses, but the user may choose to be anonymous or provide identification, which is also a feature of transparency with pseudonymity[2]; Data on blockchain is irreversibility of records. Once the transaction is recorded and updated on the chain, it is difficult to change and is permanently stored in the database, that is to say, it has the characteristics of “tamper-resistance”[3]. 　　According to Article 4 (1) of the GDPR, “personal data” means any information relating to an identified or identifiable natural person (‘data subject’); an identifiable natural person is one who can be identified, directly or indirectly, in particular by reference to an identifier such as a name, an identification number, location data, an online identifier or to one or more factors specific to the physical, physiological, genetic, mental, economic, cultural or social identity of that natural person. 　　Therefore, if data subject cannot be identified by the personal data on the blockchain, that is an anonymous data, excluding the application of GDPR. (1) What is Anonymization? 　　According to Opinion 05/2014 on Anonymization Techniques by Article 29 Data Protection Working Party of the European Union, “anonymization” is a technique applied to personal data in order to achieve irreversible de-identification[4]. 　　And it also said the “Hash function” of blockchain is a pseudonymization technology, the personal data is possible to be re-identified. Therefore it’s not an “anonymization”, the data on the blockchain may still be the personal data stipulated by the GDPR. 　　As the blockchain evolves, it will be possible to develop technologies that are not regulated by GDPR, such as part of the encryption process, which will be able to pass the court or European data protection authorities requirement of anonymization. There are also many compliance solutions which use technical in the industry, such as avoiding transaction data stored directly on the chain. 2. International data transmission 　　Furthermore, in accordance with Article 3 of the GDPR, “This Regulation applies to the processing of personal data in the context of the activities of an establishment of a controller or a processor in the Union, regardless of whether the processing takes place in the Union or not. This Regulation applies to the processing of personal data of data subjects who are in the Union by a controller or processor not established in the Union, where the processing activities are related to: (a) the offering of goods or services, irrespective of whether a payment of the data subject is required, to such data subjects in the Union; or (b) the monitoring of their behaviour as far as their behaviour takes place within the Union”.[5] 　　In other words, GDPR applies only when the data on the blockchain is not anonymized, and involves the processing of personal data of EU citizens. 3. Identification of data controllers and data processors 　　Therefore, if the encryption technology involves the public storage of EU citizens' personal data and passes it to a third-party controller, it may be identified as the “data controller” under Article 4 of GDPR, and all nodes and miners of the platform may be deemed as the “co-controller” of the data, and be assumed joint responsibility with the data controller by GDPR. For example, the parties can claim the right to delete data from the data controller. 　　In addition, a blockchain operator may be identified as a “processor”, for example, Backend as a Service (BaaS) products, the third parties provide network infrastructure for users, and let users manage and store personal data. Such Cloud Services Companies provide online services on behalf of customers, do not act as “data controllers”. Some commentators believe that in the case of private chains or alliance chains, such as land records transmission, inter-bank customer information sharing, etc., compared to public chain applications: such as cryptocurrencies (Bitcoin for example), is not completely decentralized, and more likely to meet GDPR requirements[6]. For example, in the case of a private chain or alliance chain, it is a closed platform, which contains only a small number of trusted nodes, is more effective in complying with the GDPR rules. 4. Data subject claims 　　In accordance with Article 17 of the GDPR, The data subject shall have the right to obtain from the controller the erasure of personal data concerning him or her without undue delay and the controller shall have the obligation to erase personal data without undue delay under some grounds. 　　Off-chain storage technology can help the blockchain industry comply with GDPR rules, allowing offline storage of personal data, or allow trusted nodes to delete the private key of encrypted information, which leaving data that cannot be read and identified on the chain. If the data is in accordance with the definition of anonymization by GDPR, there is no room for GDPR to be applied. IV. Conclusion 　　In summary, it’s seem that the application of blockchain to GDPR may include: (a) being difficulty to identified the data controllers and data processors after the data subject upload their data. (b) the nature of decentralized storage is transnational storage, and Whether the country where the node is located, is meets the “adequacy decision” of Article 45 of the GDPR. 　　If it cannot be met, then it needs to consider whether it conforms to the transfers subject to appropriate safeguards of Article 46, or the derogations for specific situations of Article 49 of the GDPR. Reference: [1] How to Trade Cryptocurrency: A Guide for (Future) Millionaires, https://wikijob.com/trading/cryptocurrency/how-to-trade-cryptocurrency [2] DONNA K. HAMMAKER, HEALTH RECORDS AND THE LAW 392 (5TH ED. 2018). [3] Iansiti, Marco, and Karim R. Lakhani, The Truth about Blockchain, Harvard Business Review 95, no. 1 (January-February 2017): 118-125, available at https://hbr.org/2017/01/the-truth-about-blockchain [4] Article 29 Data Protection Working Party, Opinion 05/2014 on Anonymisation Techniques (2014), https://www.pdpjournals.com/docs/88197.pdf [5] Directive 95/46/EC (General Data Protection Regulation), https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32016R0679&from=EN [6] Queen Mary University of London, Are blockchains compatible with data privacy law? https://www.qmul.ac.uk/media/news/2018/hss/are-blockchains-compatible-with-data-privacy-law.html

Recognized that Research infrastructures (RIs) are at the centre of the knowledge triangle of research, education and innovation and play an increasingly important role in the advancement of knowledge and technology, the EU began to finance for the establishments of RIs by its Framework Programmes (FPs) since the start of FP2 of 1987. On the other hand, the EU also assigned the European Strategy Forum on Research Infrastructures (ESFRI) to develop a coherent and strategy-led approach to policy-making on RIs between Member States and to facilitate the better use and development of RIs at EU and international level. Based on those efforts, the European Commission understood that a major difficulty in setting up RIs between EU countries is the lack of an adequate legal framework allowing the creation of appropriate partnerships and proposed a legal framework for a European research infrastructure adapted to the needs of such facilities. The new legal framework for a European Research Infrastructure Consortium (ERIC) entered into force on 28 August 2009. An successfully-set-up ERIC will have the legal personality based on EU law, and can benefit from exemptions from VAT and excise duty in all EU Member States and may adopt its own procurement procedures to get rid of the EU's public procurement procedures. It is predicted that the Biobanking and Biomolecular Resources Research Infrastructure (BBMRI) will apply to become a BBMRI-ERIC in the near future. The EU also seeks to lead in Energy, Food and Biology through the reforms of ERICs to assist the high quality of activities of European scientists and attract the best researchers from around the world. Besides, in order to connect the knowledge triangle effectively, the European Commission also established the European Institute of Innovation and Technology (EIT) on March 2008. It hopes through the research development partnership network to gather all the advantages from the science and technology chains of multiple areas, and make an effort for the strategy of EU innovation development jointly；Meanwhile, extends its roadmap to the objectives and practices of the Knowledge and Innovation Communities (KICs) of the EIT. Contrast with the EU's advance, it is necessary to our government to concentrate and contemplate whether it is the time to reconsider if our existing legal instruments available to domestic research facilities and infrastructures are sufficient enough to reach our science and technology development goals.

I. Introduction 　　When, Finland, this country comes to our minds, it is quite easy for us to associate with the prestigious cell-phone company “NOKIA”, and its unbeatable high technology communication industry. However, following the change of entire cell-phone industry, the rise of smart phone not only has an influence upon people’s communication and interaction, but also makes Finland, once monopolized the whole cell-phone industry, feel the threat and challenge coming from other new competitors in the smart phone industry. However, even though Finland’s cell-phone industry has encountered frustrations in recent years in global markets, the Finland government still poured many funds into the area of technology and innovation, and brought up the birth of “Angry Birds”, one of the most popular smart phone games in the world. The Finland government still keeps the tradition to encourage R&D, and wishes Finland’s industries could re-gain new energy and power on technology innovation, and indirectly reach another new competitive level. 　　According to the Statistics Finland, 46% Finland’s enterprises took innovative actions upon product manufacturing and the process of R&D during 2008-2010; also, the promotion of those actions not merely existed in enterprises, but directly continued to the aspect of marketing and manufacturing. No matter on product manufacturing, the process of R&D, the pattern of organization or product marketing, we can observe that enterprises or organizations make contributions upon innovative activities in different levels or procedures. In the assignment of Finland’s R&D budgets in 2012, which amounted to 200 million Euros, universities were assigned by 58 million Euros and occupied 29% R&D budgets. The Finland Tekes was assigned by 55 million Euros, and roughly occupied 27.5% R&D budgets. The Academy of Finland (AOF) was assigned by 32 million Euros, and occupied 16% R&D budges. The government’s sectors were assigned by 3 million Euros, and occupied 15.2% R&D budgets. Other technology R&D expenses were 2.1 million Euros, and roughly occupied 10.5% R&D. The affiliated teaching hospitals in universities were assigned by 0.36 million Euros, and occupied 1.8% R&D budgets. In this way, observing the information above, concerning the promotion of technology, the Finland government not only puts more focus upon R&D innovation, but also pays much attention on education quality of universities, and subsidizes various R&D activities. As to the Finland government’s assignment of budges, it can be referred to the chart below. 　　As a result of the fact that Finland promotes industries’ innovative activities, it not only made Finland win the first position in “Growth Competitiveness Index” published by the World Economic Forum (WEF) during 2000-2006, but also located the fourth position in 142 national economy in “The Global Competitiveness Report” published by WEF, preceded only by Swiss, Singapore and Sweden, even though facing unstable global economic situations and the European debt crisis. Hence, observing the reasons why Finland’s industries have so strong innovative power, it seems to be related to the Finland’s national technology administrative system, and is worthy to be researched. II. The Recent Situation of Finland’s Technology Administrative System A. Preface 　　Finland’s administrative system is semi-presidentialism, and its executive power is shared by the president and the Prime Minister; as to its legislative power, is shared by the Congress and the president. The president is the Finland’s leader, and he/she is elected by the Electoral College, and the Prime Minister is elected by the Congress members, and then appointed by the president. To sum up, comparing to the power owned by the Prime Minister and the president in the Finland’s administrative system, the Prime Minister has more power upon executive power. So, actually, Finland can be said that it is a semi-predisnetialism country, but trends to a cabinet system. 　　Finland technology administrative system can be divided into four parts, and the main agency in each part, based upon its authority, coordinates and cooperates with making, subsidizing, executing of Finland’s technology policies. The first part is the policy-making, and it is composed of the Congress, the Cabinet and the Research and Innovation Council; the second part is policy management and supervision, and it is leaded by the Ministry of Education and Culture, the Ministry of Employment and the Economy, and other Ministries; the third part is science program management and subsidy, and it is composed of the Academy of Finland (AOF), the National Technology Agency (Tekes), and the Finnish National Fund Research and Development (SITRA); the fourth part is policy-executing, and it is composed of universities, polytechnics, public-owned research institutions, private enterprises, and private research institutions. Concerning the framework of Finland’s technology administrative, it can be referred to below. B. The Agency of Finland’s Technology Policy Making and Management (A) The Agency of Finland’s Technology Policy Making 　　Finland’s technology policies are mainly made by the cabinet, and it means that the cabinet has responsibilities for the master plan, coordinated operation and fund-assignment of national technology policies. The cabinet has two councils, and those are the Economic Council and the Research and Innovation Council, and both of them are chaired by the Prime Minister. The Research and Innovation Council is reshuffled by the Science and Technology Policy Council (STPC) in 1978, and it changed name to the Research and Innovation Council in Jan. 2009. The major duties of the Research and Innovation Council include the assessment of country’s development, deals with the affairs regarding science, technology, innovative policy, human resource, and provides the government with aforementioned schedules and plans, deals with fund-assignment concerning public research development and innovative research, coordinates with all government’s activities upon the area of science, technology, and innovative policy, and executes the government’s other missions. 　　The Research and Innovation Council is an integration unit for Finland’s national technology policies, and it originally is a consulting agency between the cabinet and Ministries. However, in the actual operation, its scope of authority has already covered coordination function, and turns to direct to make all kinds of policies related to national science technology development. In addition, the consulting suggestions related to national scientific development policies made by the Research and Innovation Council for the cabinet and the heads of Ministries, the conclusion has to be made as a “Key Policy Report” in every three year. The Report has included “Science, Technology, Innovation” in 2006, “Review 2008” in 2008, and the newest “Research and Innovation Policy Guidelines for 2011-2015” in 2010. 　　Regarding the formation and duration of the Research and Innovation Council, its duration follows the government term. As for its formation, the Prime Minister is a chairman of the Research and Innovation Council, and the membership consists of the Minister of Education and Science, the Minister of Economy, the Minister of Finance and a maximum of six other ministers appointed by the Government. In addition to the Ministerial members, the Council shall comprise ten other members appointed by the Government for the parliamentary term. The Members must comprehensively represent expertise in research and innovation. The structure of Council includes the Council Secretariat, the Administrative Assistant, the Science and Education Subcommittee, and the Technology and Innovation Subcommittee. The Council has the Science and Education Subcommittee and the Technology and Innovation Subcommittee with preparatory tasks. There are chaired by the Ministry of Education and Science and by the Minister of Economy, respectively. The Council’s Secretariat consists of one full-time Secretary General and two full-time Chief Planning Officers. The clerical tasks are taken care of at the Ministry of Education and Culture. (B) The Agency of Finland’s Technology Policy Management 　　The Ministries mainly take the responsibility for Finland’s technology policy management, which includes the Ministry of Education and Culture, the Ministry of Employment and Economy, the Ministry of Social Affairs and Health, the Ministry of Agriculture and Forestry, the Ministry of Defense, the Ministry of Transport and Communication, the Ministry of Environment, the Ministry of Financial, and the Ministry of Justice. In the aforementioned Ministries, the Ministry of Education and Culture and the Ministry of Employment and Economy are mainly responsible for Finland national scientific technology development, and take charge of national scientific policy and national technical policy, respectively. The goal of national scientific policy is to promote fundamental scientific research and to build up related scientific infrastructures; at the same time, the authority of the Ministry of Education and Culture covers education and training, research infrastructures, fundamental research, applied research, technology development, and commercialization. The main direction of Finland’s national scientific policy is to make sure that scientific technology and innovative activities can be motivated aggressively in universities, and its objects are, first, to raise research funds and maintain research development in a specific ratio; second, to make sure that no matter on R&D institutions or R&D training, it will reach fundamental level upon funding or environment; third, to provide a research network for Finland, European Union and global research; fourth, to support the research related to industries or services based upon knowledge-innovation; fifth, to strengthen the cooperation between research initiators and users, and spread R&D results to find out the values of commercialization, and then create a new technology industry; sixth, to analyze the performance of national R&D system. 　　As for the Ministry of Employment and Economy, its major duties not only include labor, energy, regional development, marketing and consumer policy, but also takes responsibilities for Finland’s industry and technical policies, and provides industries and enterprises with a well development environment upon technology R&D. The business scope of the Ministry of Employment and Economy puts more focus on actual application of R&D results, it covers applied research of scientific technology, technology development, commercialization, and so on. The direction of Finland’s national technology policy is to strengthen the ability and creativity of industries’ technology development, and its objects are, first, to develop the new horizons of knowledge with national innovation system, and to provide knowledge-oriented products and services; second, to promote the efficiency of the government R&D funds; third, to provide cross-country R&D research networks, and support the priorities of technology policy by strengthening bilateral or multilateral cooperation; fourth, to raise and to broaden the efficiency of research discovery; fifth, to promote the regional development by technology; sixth, to evaluate the performance of technology policy; seventh, to increase the influence of R&D on technological change, innovation and society; eighth, to make sure that technology fundamental structure, national quality policy and technology safety system will be up to international standards. (C) The Agency of Finland’s Technology Policy Management and Subsidy 　　As to the agency of Finland’s technology policy management and subsidy, it is composed of the Academy of Finland (AOF), the National Technology Agency (Tekes), and the Finnish National Fund Research and Development (SITRA). The fund of AOF comes from the Ministry of Education and Culture; the fund of Tekes comes from the Ministry of Employment and Economy, and the fund of SITRA comes from independent public fund supervised by the Finland’s Congress. (D) The Agency of Finland’s Technology Plan Execution 　　As to the agency of Finland’s technology plan execution, it mainly belongs to the universities under Ministries, polytechnics, national technology research institutions, and other related research institutions. Under the Ministry of Education and Culture, the technology plans are executed by 16 universities, 25 polytechnics, and the Research Institute for the Language of Finland; under the Ministry of Employment and Economy, the technology plans are executed by the Technical Research Centre of Finland (VTT), the Geological Survey of Finnish, the National Consumer Research Centre; under the Ministry of Social Affairs and Health, the technology plans are executed by the National Institute for Health and Welfare, the Finnish Institute of Occupational Health, and University Central Hospitals; under the Ministry of Agriculture and Forestry, the technology plans are executed by the Finnish Forest Research Institute (Metla), the Finnish Geodetic Institute, and the Finnish Game and Fisheries Research Institute (RKTL); under the Ministry of Defense, the technology plans are executed by the Finnish Defense Forces’ Technical Research Centre (Pvtt); under the Ministry of Transport and Communications, the technology plans are executed by the Finnish Meteorological Institute; under the Ministry of Environment, the technology plans are executed by the Finnish Environment Institute (SYKE); under the Ministry of Financial, the technology plans are executed by the Government Institute for Economic Research (VATT). At last, under the Ministry of Justice, the technology plans are executed by the National Research Institute of Legal Policy.

Experiences about opening data in private sector Ⅰ. Introduction 　　Open data is the idea that data should be available freely for everyone to use and republish without restrictions from copyright, patents or other mechanisms of control. The concept of open data is not new; but a formalized definition is relatively new, and The Open Definition gives full details on the requirements for open data and content as follows: 　　Availability and access: the data must be available as a whole with no more than a reasonable reproduction cost, preferably by downloading over the internet. The data must also be available in a convenient and modifiable form. 　　Reuse and redistribution: the data must be provided under terms that permit reuse and redistribution including the intermixing with other datasets. The data shall be machine-readable. 　　Universal participation: everyone must be able to use, reuse and redistribute the data— which by means there should be no discrimination against fields of endeavor or against persons or groups. For example, “non-commercial” restrictions that would prevent “commercial” use, or restrictions of use for certain purposes are not allowed. 　　In order to be in tune with international developmental trends, Taiwan passed an executive resolution in favor of promoting Open Government Data in November 2012. Through the release of government data, open data has grown significantly in Taiwan and Taiwan has come out on top among 122 countries and areas in the 2015 and 2016 Global Open Data Index[1]. 　　The result represented a major leap for Taiwan, however, progress is still to be made as most of the data are from the Government, and data from other territories, especially from private sector can rarely be seen. It is a pity that data from private sector has not being properly utilized and true value of such data still need to be revealed. The following research will place emphasis to enhance the value of private data and the strategies of boosting private sector to open their own data. Ⅱ. Why open private data 　　With the trend of Open Government Data recent years, countries are now starting to realize that Open Government Data is improving transparency, creating opportunities for social and commercial innovation, and opening the door to better engagement with citizens. But open data is not limited to Open Government Data. In fact, the private sector not only interacts with government data, but also produces a massive amount of data, much of which in need of utilized. 　　According to the G20 open data policy agenda made in 2014, the potential economic value of open data for Australia is up to AUD 64 billion per annum, and the potential value of open data from private sector is around AUD 34 billion per annum. Figure 1 Value of open data for Australia (AUD billion per annum) Source: McKinsey Global Institute 　　The purpose for opening data held by private entities and corporations is rooted in a broad recognition that private data has the potential to foster much public good. Openness of data for companies can translate into more efficient internal governance frameworks, enhanced feedback from workers and employees, improved traceability of supply chains, accountability to end consumers, and with better service and product delivery. Open Private Data is thus a true win-win for all with benefiting not only the governance but environmental and social gains. 　　At the same time, a variety of constraints, notably privacy and security, but also proprietary interests and data protectionism on the part of some companies—hold back this potential. Ⅲ. The cases of Open Private Data 　　Syngenta AG, a global Swiss agribusiness that produces agrochemicals and seeds, has established a solid foundation for reporting on progress that relies on independent data collection and validation, assurance by 3rd party assurance providers, and endorsement from its implementing partners. Through the website, Syngenta AG has shared their datasets for agricultural with efficiency indicators for 3600 farms for selected agro-ecological zones and market segments in 42 countries in Europe, Africa, Latin America, North America and Asia. Such datasets are precious but Syngenta AG share them for free only with a Non-Commercial license which means users may copy and redistribute the material in any medium or format freely but may not use the material for commercial purposes. Figure 2 Description and License for Open data of Syngenta AG Source: http://www.syngenta.com 　　Tokyo Metro is a rapid transit system in Tokyo, Japan has released information such as train location and delay times for all lines as open data. The company held an Open Data Utilization Competition from 12 September to 17 November, 2014 to promote development of an app using this data and continues to provide the data even after the competition ended. However, many restrictions such as non-commercial use, or app can only be used for Tokyo Metro lines has weakened the efficiency of open data, it is still valued as an initial step of open private data. Figure 3 DM of Tokyo Metro Open data Contest Source: https://developer.tokyometroapp.jp/ Ⅳ. How to enhance Open Private Data 　　Open Private Data is totally different from Open Government Data since “motivation” is vital for private institutions to release their own data. Unlike the government data can be disclosed and free to use via administrative order or legislation, all of the data controlled by private institutions can only be opened under their own will. The initiative for open data therefore shall focus on how to motivate private sectors releasing their own data-by ensuring profit and minimizing risks. 　　Originally, open data shall be available freely for everyone to use without any restrictions, and data owners may profit indirectly as users utilizing their data creating apps, etc. but not profit from open data itself. The income is unsteady and data owners therefore lose their interest to open data. As a countermeasure, it is suggested to make data chargeable though this may contradict to the definition of open data. When data owners can charge by usage or by time, the motivation of open data would arise when open data is directly profitable. 　　Data owners may also worry about many legal issues when releasing their own data. They may not care about whether profitable or not but afraid of being involved into litigation disputes such as intellectual property infringement, unfair competition, etc. It is very important for data owners to have a well protected authorization agreement when releasing data, but not all of them is able to afford the cost of making agreement for each data sharing. Therefore, a standard sample of contract that can be widely adopted plays a very important role for open private data. 　　A data sharing platform would be a solution to help data owners sharing their own data. It can not only provide a convenient way to collect profit from data sharing but help data owners avoiding legal risks with the platform’s standard agreement. All the data owners have to do is just to transfer their own data to the platform without concern since the platform would handle other affairs. Ⅴ. Conclusion 　　Actively engaging the private sector in the open data value-chain is considered an innovation imperative as it is highly related to the development of information economy. Although many works still need to be done such as identifying mechanisms for catalyzing private sector engagement, these works can be done by organizations such as the World Bank and the Centre for Open Data Enterprise. Private-public collaboration is also important when it comes to strengthening the global data infrastructure, and the benefits of open data are diverse and range from improved efficiency of public administrations to economic growth in the private sector. However, open private data is not the goal but merely a start for open data revolution. It is to add variation for other organizations and individuals to analyze to create innovations while individuals, private sectors, or government will benefit from that innovation and being encouraged to release much more data to strengthen this data circulation. [1] Global Open Data Index, https://index.okfn.org/place/（Last visited: May 15, 2017）