Hi @Thommy7571,
Sorry for the delay, your responses were in the spam folder, I just marked them as "safe".
@Thommy7571 wrote:
In your design red points are on the corners of the cube and marked as points for the DSD. This is not possible according to the article of Bayiley. These are simple factorail points - at least in case of two levels. e.g. +1, +1, +1 so such points -cannot be in a DSD.
You can have "simple factorial" points in your design if you have a very low number of factors : less factors than 5 will still create designs with 13 runs, so you might end up with factorial points. This 13-runs design is in fact a DSD with 5 factors and the minimum number of runs, projected in a 3 factors dimensional space. Take into account projection property of factorial-based designs (DSD, CCD and others) : if one of the k factors is not important/active, you can still project the experiments in a k-1 dimension experimental space, which could give you the impression that you have factorial points.
More info here : https://www.linkedin.com/posts/victorguiller_designofexperiments-statistics-dataanalytics-activity-7...
Hope that clarifies this point.
@Thommy7571 wrote:
In general it is recommended to take for +1 and -1 the extreme values of a parameter. Starpoints would be out of the range, no? If so, how can I take points outside the limits if this is physically impossible? What are recommended experimental values to be used for +1 and -1 compared to the limiting values (concentration e.g. 0 % and 100 % - less or more is not possible!)
It depends what is the value for your axial point, as you could have a circumscribed (>1), face-centered (=1) or inscribed (<1) Central Composite design.
The choice of the value for the star point is a compromise between physical feasability of the runs (can you extend the factors range below the -1 or above +1 coded values) and the objective(s) behind your CCD. On a similar topic, I showed that the farthest the star points are from the centre of the experimental space :
- The higher the power for main effects and quadratic effects, but the lower the power for the intercept,
- The higher the variance in the centre of the experimental space, but the lower the variances at the border of the experimental space.
You can read more here: https://community.jmp.com/t5/Discussions/why-are-no-star-points-in-custom-design-RSM/m-p/603144/high...
@Thommy7571 wrote:
Am I right or is there nothing on DSDs on Nist.gov? Is it finally perhaps not a good idea - using 6 or 7 factors - to start with a DSD if runs cannot be reasonably used for the following design? Why did nobody decvelop a design similar to CCD which bases on the DSD, since the latter is so useful for the gain of information?
I haven't seen updates about Definitive Screening Designs on Nist.gov. You can check here the recent updates : : https://www.itl.nist.gov/div898/handbook/index.htm
Definitive Screening Design are very helpful at screening main effects and detecting possible strong higher order effects such as 2-factors interactions and quadratic effects. They are very powerful when dealing with 5+ factors, as they can significantly reduce the required number of runs compared to classical design approaches.
You can always use runs from any design using the platform Augment Designs. If you have run a DSD, you can augment your design into a Response Surface model design, very similarly to what you could get with a classical sequential approach with CCD.
The main benefit of the DSD is to start investigate non-linear quadratic effects from the screening phase : it avoids "binary" responses and discard a statstically non-significant factor that could have a quadratic effect.
Hope this clarifies your doubts, and that the elements provided will help you find a solution,
Victor GUILLER
"It is not unusual for a well-designed experiment to analyze itself" (Box, Hunter and Hunter)