References
- Andersson, P. M., Lundstedt, T. & Abramo, L. (1996). Synthesis and optimisation of 1-pyrrolemethane sulfonate by means of experimental design. Journal of Chemometrics, 10, 379-384.
- Antony, J. (2014). Some Useful and Practical Tips for Making Your Industrial Experiments Successful. In J. Antony (Ed.), Design of Experiments for Engineers and Scientists. Second Edition (pp. 113-123). Elsevier. doi: 10.1016/B978-0-08-099417-8.00008-0
- Antony, J., & Roy, R. K. (1999). Improving the process quality using statistical Design of experiments: A case study. Quality Assurance, 6, 87-95.
- Arnoldsson, K. C., & Kaufmann, P. (1994). Lipid class analysis by normal phase high performance liquid chromatography, development and optimisation using multivariate methods. Chromatographia, 38, 317-324.
- Beijersten, I., & Westerlund, D. (1995). Derivatisation Of Dipeptides With 4-Fluoro-7-Nitro2,1,3 Benzoxadiazole For Laser-Induced Fluorescence And Separation By Micellar Electrokinetic Chromatography. Journal of Chromatography, 716, 389-399.
- Bisgaard, S. (1991). Teaching Statistics to Engineers. The American Statistician, 45(4), 274-283.
- Bisgaard, S. (1992). Industrial use of statistically designed experiments: Case study references and some historical anecdotes. Quality Engineering, 4, 547-562.
- Box G. E. P., Bisgaard, S., & Fung, C. (1988). An explanation and critique of Taguchi’s contributions to quality engineering. Quality and Reliability Engineering International, 4, 123-131.
- Box, G. E. P. (1988). Signal-to-noise ratios, performance criteria, and transformation. Technometrics, 30, 1-40.
- Box, G. E. P. (2001). Statistics for discovery. Journal of Applied Statistics, 28(3-4), 285-299.
- Box, G. E. P., Hunter, W. G. J., & Hunter, S. (1987). Statistics for experimenters: an introduction to Design,
- Brady, J. E., & Allen, T. T. (2006). Six Sigma literature: A review and agenda for future research. Quality and Reliability Engineering International, 22, 335-367.
- Bucher, R. A., & Loos, A. C. (1994). Parametric statistical analysis of electrostatic powder prepregging. Journal of Advanced Materials, 25, 44-50.
- Bzik, T. J., Henderson, P. B., & Hobbs, J. P. (1998). Increasing the precision and accuracy of top loading balances: Application of experimental design. Analytical Chemistry, 70, 58-63.
- Carlson, A. D., Hofer, J. D., & Riggin, R. M. (1997). Development of an optimised peptide map for recombinant activated human protein c by means of an experimental design strategy. Analytica Chimica Acta, 352, 221-230.
- Chapin, S. F. (1950). Research note on randomisation in a social experiment. Science, 112, 760-761.
- Chen, H. C. (1996). Optimising the concentrations of carbon, nitrogen and phosphorus in a citric acid fermentation with response surface method. Food Biotechnology, 10, 13-27.
- Czitrom, V. (1999). One factor at a time versus Designed Experiments. The American Statistician, 53(2), 126-131.
- data analysis, and model building. New York: Wiley.
- Davim, J. P. (Ed.). (2016). Design of Experiments in Production Engineering. Springer International Publishing.
- Davis, B. L., Cavanagh, P. R., Sommer, H. J., & Wu, G. (1996). Ground reaction forces during locomotion in simulated microgravity. Aviation Space and Environmental Medicine, 67, 235-242.
- Durakovic, B. (2017). Design of Experiments Application, Concepts, Examples: State of the Art. Periodicals of Engineering and Natural Sciences, 5(3), 421-439. doi: 10.21533/pen
- Durakovic, B., & Torlak, M. (2017). Simulation and experimental validation of phase change material and water used as heat storage medium in window applications. Journal of Materials and Environmental Science, 8(5), 1837-1746.
- Fisher, R. A. (1926). The arrangement of field experiments. Journal of the Ministry of Agriculture of Great Britain, 33, 503-513.
- Gardner, R., Bieker, J., Elwell, S., Thalman, R., & Rivera, E. (2000). Solving tough semiconductor manufacturing problems using data mining. In Proceedings of IEEE/SEMI Advanced Semiconductor Manufacturing Conference and Workshop, 46-55.
- Goh, T. N. (2002). The role of statistical Design of Experiments in Six Sigma: Perspectives of a practitioner. Quality Engineering, 14(4), 659-671.
- Gremyr, I., Arvidsson, M., & Johansson, P. (2003). Robust Design Methodology: Status in the Swedish Manufacturing Industry. Qualitative Reliability Engineering International, 19, 285-293.
- Hahn, G. J. (2005). Six Sigma: 20 Key Lessons Learned. Quality and Reliability Engineering International, 21, 225-233.
- Hecht, E. S., Oberg, A. L., & Muddiman, D. C. (2016). Optimising Mass Spectrometry Analyses: A Tailored Review on the Utility of Design of Experiments. Journal of American Society of Mass Spectrometry, 27, 767-785.
- Hibbert, D. B. (2012). Experimental design in chromatography: a tutorial review. Journal of Chromatography, 910, 2-13.
- Ilzarbe, L., Álvarez, M. J., Viles, E., & Tanco, M. (2008). Practical applications of design of experiments in the field of engineering: a bibliographical review. Qualitative Reliability Engineering International, 24, 417-428.
- Kackar, R. N., & Shoemaker, A. C. (2021). Robust Design: A cost-effective method for improving manufacturing processes. AT&T Technical Journal, 65, 39-50.
- Kenett, R. S., & Steinberg, D. M. (2006). New frontiers in the Design of experiments. Quality Progress, 39(8), 61-65.
- Lye, L. M. (2005). Tools and toys for teaching design of experiments methodology. In 33rd Annual General Conference of the Canada, Toronto, Ontario, Canada.
- Mager, P. P. (1997). How design statistics concepts can improve experimentation in medicinal chemistry. Medicinal Research Reviews, 17, 453-475.
- Montgomery, D. C. (2017). Design and Analysis of Experiments. John Wiley & Sons, Inc.
- Myers, R. H., Montgomery, D. C., Vining, G. G., Borror, C. M., & Kowalski, S. M. (2004). Response surface methodology: A retrospective and literature survey. Journal of Quality Technology, 36(1), 53-77.
- Nair, V. N. (1992). Taguchi’s parameter design: A panel discussion. Technometrics, 34, 127-161.
- Okatia, V., Behzadmehra, A., & Farsad, S. (2016). Analysis of a solar desalinator (humidification–dehumidification cycle) including a compound system consisting of a solar humidifier and subsurface condenser using DoE. Desalination, 397, 9-21.
- Paulo, F., & Santos, L. (2017). Design of experiments for microencapsulation applications: A review. Materials Science and Engineering: C, 77(August), 1327-1340.
- Puente-Massaguer, E., Lecina, M., & Gòdia, F. (2020). Integrating nanoparticle quantification and statistical design of experiments for efficient HIV-1 virus-like particle production in High Five cells. Applied Microbiology and Biotechnology, 104, 1569-1582. doi: 10.1007/s00253-019-10319-x
- Robinson, T. J., Borror, C. M., & Myers, R.H. (2004). Robust parameter design: A review. Quality and Reliability Engineering International, 20, 81-101.
- Schlueter, A., & Geyer, P. (2018). Linking BIM and Design of Experiments to balance architectural and technical design factors for energy performance. Automation in Construction, 86(February), 33-43.
- Setamanit, S. (2018). Evaluation of outsourcing transportation contract using simulation and design of experiment. Polish Journal of Management Studies, 18(2), 300-310.
- Sukthomya, W., & Tannock, J. (2005). The optimisation of neural network parameters using Taguchi’s design of experiments approach: an application in manufacturing process modelling. Neural Computing and Applications, 14, 337-344. doi: 10.1007/s00521-005-0470-3
- Tukey, J. W. (1947). Non-parametric estimation II. Statistically equivalent blocks and tolerance regions – the continuous case. Annals of Mathematical Statistics, 18, 529-539.
- Wald, A. (1943). An extension of Wilks’ method for setting tolerance limits. Annals of Mathematical Statistics, 14, 45-55.
- Wesling, P., & Emamjomeh, A. (1994). T.A.B. Innerlead bond process characterisation for single point laser bonding. IEEE Transactions on Components Packaging & amp. Manufacturing Technology Part A, 17, 142-148.
- Yang, G. C. C., & Tsai, C. M. (1998). A study on heavy metal extractability and subsequent recovery by electrolysis for a municipal incinerator fly ash. Journal of Hazardous Materials, 58, 103-120.
- Yip, H. M., Wang, Z., Navarro-Alarcon, D., Li, P., Cheung, T. H., Greiffenhagen, Ch., & Liu, Y. (2020). A collaborative robotic uterine positioning system for laparoscopic hysterectomy: Design and experiments. International Journal of Medical Robotics and Computer Assisted Surgery, 16(4), e2103. doi: 10.1002/rcs.2103
- Yondo, R., Andrés, E., & Valero, E. (2018). A review on design of experiments and surrogate models in aircraft real-time and many-query aerodynamic analyses. Progress in Aerospace Sciences, 96, 23-61. doi: 10.1016/j.paerosci.2017.11.003
- Yoo, K. S. (2020). Application of Statistical Design of Experiments in the Field of Chemical Engineering: A Bibliographical Review. The Korean Society of Industrial and Engineering Chemistry, 31(2), 138-146. doi: 10.14478/ACE.2020.1018
- Yu, P., Low, M. Y., & Zhou, W. (2018). Design of experiments and regression modelling in food flavour and sensory analysis: A review. Trends in Food Science & Technology, 71(January), 202-215.
- Zheng, H., Clausen, M. R., Dalsgaard, T. K., Mortensen, G., & Bertram, H. C. (2013). Time-saving design of experiment protocol for optimisation of LC-MS data processing in metabolomic approaches. Analytical Chemistry, 85, 7109-7116.