The parameters of a design have to fulfil certain restrictions. They arise from the fact that a t-design D is also a s-design for any s <= t.
In order to proof this, take an arbitrary s-subset S in the point set V and count the number of pairs (T, B) where T is a t-subset of V containing S, B is a block of the t-design containing T. We have two possibilities to count:
lambdas = lambda · (v-s \choose t-s) / (k-s \choose t-s)
So D is an s-(v, k, lambdas) design for all s <= t.
But this equation (actually we have t+1 equations - one for each s in {0, ..., t}) yields restrictions on the parameter sets {t, v, k, lambda}, because all the lambdas have to be integers. A parameter set which fulfils these restrictions is called admissible parameter set.
Let delta_lambda be the lcm of the denominators in the second equation above for all s <= t. Then all parameter sets of the form t-(v, k, h · delta_lambda) with any natural number h are admissible. Thus the calculation of delta_lambda is essential. In order to do that with DISCRETA, you have to press the button "Parameters" and receive the following table:
By choosing "\lambda_i" you start the calculation of all the lambdas and delta_lambda. They are shown in the DISCRETA-window as well as on the terminal, where you started DISCRETA. Two short examples:
v=15 t=2 k=3 lambda=1
t'=1 lambda'=7/1 delta_lambda=1
t'=0 lambda'=35/1 delta_lambda=1
The lambda' are all integral and delta_lambda=1, so this parameter set is admissible and even the parameter sets 2-(15, 3, lambda) with a natural number lambda is admissible.
v=15 t=2 k=7 lambda=1
t'=1 lambda'=7/3 delta_lambda=3
t'=0 lambda'=5/1 delta_lambda=3
So the parameters are not admissible, because 7/3 is not integral. But the parameter sets 2-(15, 7, h · 3) are admissible for any natural number h.
Remark: You have to click on the pictures to get them largely.
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Last updated: August 24, 1999, Evi Haberberger