1 |
H. S. Kim, D. D. Lee & H. S. Kim. (2014). Strategies and Tasks of ICT Convergence for the Creative Agriculture Realization(R736), Seoul: Korea Rural Economic Institute.
|
2 |
T. Y. Lee & C. M. Heo. (2019). A Study on the Influence of Acceptance Factors of ICT Convergence Technology on the Intention of Acceptance in Agriculture : Focusing on the Moderating Effect of Innovation Resistance. Journal of Digital Convergence, 17(9), 115-126.
|
3 |
M. H. Ahn & C. M. Heo. (2019). The Effect of Technical Characteristics of Smart Farm on Acceptance Intention by Mediating Effect of Effort Expectation. Journal of Digital Convergence, 17(6), 145-157.
DOI
|
4 |
N. G. Yoon, J. S. Lee, G. S. Park & J. Y. Lee. (2017). Korea smart farm policy and technology development status. Rural Resources, 59(2), 19-27.
|
5 |
Ministry of Economy and Finance. (2018. 08. 13). 5th Innovation Growth Ministerial Meeting-Strategic Investment Direction for Innovation Growth. MOEF(Online), http://www.moef.go.kr/nw/nes/detailNesDtaView.do?menuNo=4010100&searchNttId1=MOSF_000000000018581&searchBbsId1=MOSFBBS_000000000028
|
6 |
U. H. Yeo, I. B. Lee, K. S. Kwon, T. H Ha, S. J. Park, R. W. Kim, and S. Y. Lee. (2016). Analysis of Research Trend and Core Technologies Based on ICT to Materialize Smart-farm. Protected Horticulture and Plant Factory, 25(1), 30-41.
DOI
|
7 |
J. Y. Yoon & B. H. Lee. (2017). Implementation strategy and development methods for smart farms in Gangwon Province. Journal of Agricultural, Life and Environmental Sciences, 29, 137-151.
|
8 |
S. J. Oh. (2017). A Design of intelligent information system for greenhouse cultivation. Journal of Digital Convergence, 15(2), 183-190.
DOI
|
9 |
Smart Farm Korea. (2019. 10). Structure of smart greenhouse. EPIS(online). https://www.smartfarmkorea.net/contents/view.do?menuId=M01010103
|
10 |
S. H. Lee. (2018). The Fundamental Functionality Design of a Smart Farm Using an Embedded Computing Platform. Journal of The Institute of Electronics and Information Engineers, 55(4), 557-563.
|
11 |
LINK4. (2019. 10). LINK4 Cloud-Based Greenhouse Controls. LINK4(online). http://link4controls.com
|
12 |
RASPBERRY PI FOUNDATION. (2019. 10). Raspberry Pi 3 Model B+. RASPBERRY PI FOUNDATION(online). https://www.raspberrypi.org/products/raspberry-pi-3-model-b-plus/
|
13 |
RASPBERRY PI FOUNDATION. (2019. 10). Raspbian, RASPBERRY PI FOUNDATION. https://www.raspberrypi.org/downloads/raspbian/
|
14 |
NGiNX. (2019. 10). Learn how to configure caching, load balancing, cloud deployments, and other critical NGINX features. NGiNX(online). https://nginx.org/en/
|
15 |
The Chromium Projects. (2019. 10). chromium. The Chromium Projects(online). https://www.chromium.org/Home
|
16 |
Amazon. (2019. 10). Amazon Web Services. AWS(online). https://aws.amazon.com/ko/
|
17 |
Amazon. (2019. 10). Amazon Aurora. AWS(online). https://aws.amazon.com/ko/rds/aurora/?hp=tile&so-exp=below
|
18 |
Amazon. (2019. 10). Amazon EC2. AWS(online). https://aws.amazon.com/ko/ec2/?hp=tile&so-exp=below
|