- Email: [email protected]
Resistance of block designs
Journal
of Statistical
Planning
and Inference
27 (1991) 263-269
263
North-Holland
Resistance of block designs Rajeshwar
Singh
Department of Statistics, Institute of Advanced Studies, Meerut University, Meerut, India
V.K.
Gupta
Indian Agricultural Statistics Research Institute, New Delhi 110012, India Received
14 December
Recommended
1988; revised
by AS.
manuscript
received
(1974) introduced
resistant
Abstract: Hedayat
and
designs.
were essentially
degree
The results
one. This paper
well as universally resistant
designs
23 February
1990
Hedayat
John extends
optimal of degree
on locally/globally
the concept
of resistance
block designs with unequal
and susceptible resistant
balanced
to general
variance
balanced
incomplete
block
incomplete
block designs
of
balanced
block designs
as
block sizes. Some methods
of constructing
locally
one have been given.
AMS Subject Classification: Primary Key words and phrases: Resistant
62KlO;
designs;
secondary
variance
05B05.
balanced
designs;
universally
optimal
designs.
1. Introduction Consider a block design d in b blocks, u treatments and u x b incidence matrix Nd = (nd$, where ndi; is the replication number of the i-th treatment in the j-th blockofd,i=l,..., ; , . . . , b. The row and column sums of Nd are respectively the elements of Yd =‘;r”= d,,..’.,rd")' and kd = (k,, 1.. , I$,)‘. Further, let R, = diag (l;di, . . . , r&,)
and
& = diag (kdi, . . . , k&).
Under the usual homoscedastic, fixed effects, additive model, the coefficient matrix of the reduced normal equations for estimating the linear functions of treatment effects is c,=R,-N,K,-‘h$.
(1.1)
We shall deal only with connected designs throughout this paper. For definitions and some notations reference may be made to Kageyama (1987). Hedayat and John (1974) introduced and studied resistant balanced incomplete block (BIB) designs. Other results concerning resistance of BIB designs known so far are those given by Most (1975), Shah and Gujarathi (1977, 1983), Chandak 0378-3758/91/$03.50
0
1991-Elsevier
Science
Publishers
B.V. (North-Holland)
264
R. Singh,
V.K.
Gupta / Resistance
of block designs
(1980), Kageyama (1982, 1987) and Kageyama and Saha (1987). Kageyama (1987) proposed the idea of investigating resistant variance balanced designs. Such examples are found in Kageyama (1974, 1976). The purpose of this article is to study locally resistant variance balanced block designs. In Section 2, we study the characterization and construction of locally resistant variance balanced designs of degree one. This article also proposes to extend the concept of local resistance to universally optimal block designs. Pal and Pal (1987) studied the universal optimality of nonproper variance balanced designs in the class of designs D(o; b; k,, . . . , kb), where D(o;b;k,, . ..) kb) denotes the class of all connected designs in o treatments, b blocks and fixed block sizes k ,, . . . , k,. In Section 3, the concept of locally resistant variance balanced designs is extended to locally resistant universally optimal designs. Some series of resistant universally optimal designs of degree one and more are given. These designs are also locally resistant variance balanced designs. An important point about locally resistant universally optimal designs is that the class of resulting designs is different from the class of original designs. This happens with locally resistant BIB and variance balanced designs also. The original design has u+ 1 treatments while the resulting design has only u treatments and therefore the classes of designs in which the original and the resulting designs are optimal is bound to be different. But what is important is that the optimality is retained in the resulting design after losing information.
2. Resistant
variance
balanced
block designs
This section obtains a necessary and sufficient condition for a variance balanced block design to be resistant of degree one. Without any loss of generality, let Nd, as given in (2.1), be the incidence matrix of a variance balanced design d,
(2.1) It is assumed that the first treatment appears in the first m blocks, p’=@, . . . ,p,J andp’J=r,, where J, is a tx 1 vector of ones. Let k =(k’,,k;) denote the b x 1 vector of block sizes, where k, = (k,, . . . , k,)’ is the m x 1 vector of first m block sizes kb)’ is the (b-m) x 1 vector of the remaining b-m block sizes. and k*=(k,+,,..., Also let k, = k, -p. Similarly r= (r,,r;)’ denotes the u x 1 vector of replication the vector of the last o- 1 replication numbers with r2 = (r2, . . . , ro)’ denoting numbers. We shall denote by R,, K, K,, K2 and JCs diagonal matrices with successive elements of the vectors rz, k, k,, k2 and k3 on the diagonals respectively. Let 6 (> 0) denote the common value of the off-diagonal elements of N,ZC’Ni. Also denote by
K4 = dM(k, -pJklA
. . . , W,,,-n,&h,J.
265
R. Singh, V.K. Gupta / Resistance of block designs
Then
it is easy to see that
R,-- N,K;‘N;
- N,K;‘N;
= &(I,_,
- JJ’/v).
Let 25 be the design obtained after deleting the first treatment from parameters of a are D= u- 1, 6= 6, ~=r,, k= (k;, ki)’ and incidence NJ= [N,, N2]. The C-matrix of a is Cd= R, - N,K;‘N;
= R, - N,K,‘N;
d. The matrix
- N,KF’N; - N,K,-‘N; - N,K,-‘N;.
It therefore follows that il is variance balanced if and only if N,K;‘N’, = al,_ I + /3JJ’, (x2 0, /I? 0 and cr + (u - l)p= 6. We thus have the following theorem: Theorem
2.1. A necessary and sufficient
design to be resistant cw+(u- l)P=S.
condition for a variance balanced block of degree one is that N,Ki’N’, =aZ,_, +/lJJ’, with
Remark 2.1. The above theorem gives a mathematical characterization of locally resistant variance balanced designs in terms of N,. It would be interesting to get this in terms of design parameters, but it does not appear to be possible. We now give some methods designs of degree one.
of constructing
locally
resistant
variance
balanced
2.1. Forpositive integers p, n and m =p(n + l)/@ + 1) there exists a locally resistant variance balanced design of degree one with parameters v= n + 2, b = m + n + 1, r = ((n + l),(m +p)JL +,)‘, k = ((n + l)J&,(p + 1)JA + i)’ and incidence matrix
Method
0; J’,
Nd=
(2.2)
i J,Jin Proof.
Removing N, =
1)=6
0,
the first treatment
oil PZ,
K,=P(P+ and cx+p(u-
PZ,,
from d gives
P 0, 1 ’ ~)Z,,+I,
WG’N’,=b’t~+1)1~,+~,
for cr=6=p/(p+
1) and p=O.
2.2. Let Nd be the incidence matrix of a variance balanced block design d with parameters v, b, r and k and common value of the off-diagonal elements of
Method
266
R. Singh, V.K. Gupta / Resistance
of block designs
- Cd matrix of Nd as 6. Then for any integer a (2 0), there exists a locally resistant variance balanced design d * of degree one with incidence matrix N$=
0; . . . 0; Nd . . . Nd ” /
I,
(a + l)JL I,+aJJ’ 1
m times b*=bm+v,
and parameters v *=v+l, r*=(v(a+
l), mr’+(av+
k*=(k’, . . . . k’, (au + a + 2)JI)‘,
l)J’)‘,
if ma= (a(vProof.
Removing
1)+2)-l.
l)+ l}{a(v+
from d* gives
the first treatment
N, = I, + aJJ’,
K4 = { t/(a + 1)}1,,
= {(a+ l>/t}{Z,+
N,K:‘N;
(a2v+ 2a)JJ’},
Example
2.1.
j? = (a2v +-2a)(a + 1)/t.
a=(a+ 1)/t,
t = (au + a + 2)(av + l), Let Nd be a BIB design
with parameters
v = 6, b = 10, r= 5, k = 3,
L=2. Then for a= 1, Nd*=
06 Nd
2 J; Z,+JJ
I
is the incidence matrix of a locally resistant with respect to the first treatment.
variance
balanced
design of degree one
Method 2.3. Consider a BIB design d, with parameters v’, b’= v’(v’- 1)/k, r’ = v’- 1, k, A’ = k - 1 and incidence matrix N. Then there exists a locally resistant variance balanced design d * of degree one with parameters v = VI+ 1, b = b’+ v’,
r = ((r’+ k - l)JI,v’)‘, k = kJb and incidence matrix
Np=
Proof.
On
N o;,
removing
K4 = k(k - l)Z,,, and (k-1)/k and a=O.
(k - l)Z,, J;,
1.
(2.3)
the v-th treatment from d*, we have N1 = (k- l)I,,, N,K;‘N; = [(k - l)/k]I,. Also (Y+/3(0 - 1) = 6 for a = 6 =
We now give some series of BIB designs
dl used in the method
just described.
R. Singh, V.K. Gupta / Resistance of block
designs
(i) If tk+ 1 is a prime or prime power and x is a primitive root of GF(tk+ then the t initial sets (2, A!+‘, . . . ,2”‘k- ‘)(), i=O, 1, . . . , t - 1, form a difference
261
l), set
for a BIB design with parameters u = tk+ 1, b = t(tk+ l), r= tk, k, A = k - 1. (ii) If 4t- 1 is a prime or a prime power and x is a primitive root of GF(4tl), then the initial sets (0, 2, 2,. . . ,x4”- “), (03, x, 2, . . . ,x~‘-~) form a difference set of a BIB design with the parameters u=4t, b=2(4t- l), r=4t- 1, k=2t, A=2t- 1.
3. Resistance
of optimal
designs
This section studies the resistance of universally optimal block designs. If a universally optimal design d belonging to certain class D remains invariant under loss or deletion of some (or any) t treatments then d is said to be locally (globally) resistant of degree t. The design d is invariant if the resulting design obtained upon deleting or losing t treatments remains universally optimal over a certain class. Example 3.1. and incidence
Consider matrix
a design with parameters
u = 8, b = 14, r= 14, k = (12J;,4J;)
21112120111010 22111210011101 12211121001110
Nd=
21221110100111 12122111010011 11212211101001 11121221110100 22222220000000
This design is universally optimal over D(8; 14; 12&4J;). It is locally resistant of degree one with respect to the last treatment because the design obtained after deleting the last treatment is also universally optimal over D(7; 14; lOJ;,4J;). We now have the following
results:
The existence of a BIB design d with parameters v, b, r, k, A such that b f 21= 3r and incidence matrix Nd implies the existence of a locally resistant universally optimal design d * of degree one and parameters v * = v + 1, b * = 2b, r*=2b 9 Theorem
3.1.
k*= [(u+k+2)J;, and incidence matrix
(u-k)Jh]‘,
268
R. Singh,
V.K. Gupta / Resistance of block designs
where fid = J,,Jh - Nd. Proof. The proof follows by noting that the design obtained treatment is universally optimal over
D(o;b*;{(u+k)J;, For BIB designs satisfying John (1974, p. 154).
after deleting
the last
(u-k)J;)‘). b + 2A = 3r, reference
may be made to Hedayat
and
3.2. The existence of a symmetric BIB design d with parameters v = b, r = k, A and incidence matrix Nd implies the existence of a locally resistant universally optimal design d* of degree k or u - k and parameters o * = v, b * = b + t, Theorem
r*=(r+ab+st)J,,,
k * = [(k + au)Jb, suJi] ’
and incidence matrix Nd* = [Nd + aJ,Jb
sJ,J;].
Proof. It is easy to verify that the design d* is universally optimal over consider the first column of D(v*; b*;k;: . . . . k,*,). Without any loss of generality, N& Delete from Nd* the k treatments corresponding to the element one in the first column of N& It is known that if we delete any k treatments which appear in the same block of a symmetric BIB design then the resulting design is BIB with parameters u, = u-k, b, = u - 1, r, = k, k, = k - A, A. Using this fact it follows that optimal over D(u- k, b*, k**) where the resulting design d ** is universally
k,**= i
a(u - k) k-A+a(u-k) s(u - k)
ifj=l, ifj=2,...,b, ifj=b+ l,...,b*.
The design d** is therefore locally resistant of degree k. SimilarIy if we delete the u-k treatments corresponding to the element zero in the first column of Nd from Nd*, then the resulting design is locally resistant of degree u-k. Remark 3.1. The designs given in Theorems variance balanced designs.
3.1 and 3.2 are also locally
resistant
Acknowledgements The authors are thankful to the referees for their valuable suggestions to a considerable improvement in the presentation of the results.
which led
R. Singh,
V.K. Gupta
/ Resistance
of block designs
269
References Chandak,
M.L. (1980). On the theory
Hedayat,
A. and P.W.M.
Kageyama,
S. (1974).
rangements. Kageyama, Kageyama, Rept. Kageyama, Statist.
Reduction
Hiroshima
of resistant
John (1974). Resistant Math.
of associate
block designs. and susceptible
classes
for block
Calcufta Statist. Assoc. BIB designs. designs
Ann.
and related
Bull. 29, 27-34.
Statist.
2, 1488158.
combinatorial
S. (1976). Construction of balanced block designs. Utilitas Math. 9, 209-229. S. (1982). The existence of locally resistant BIB designs of degree one. Stat-Math. No. 18/82,
Tech.
ISI, Calcutta.
S. (1987). Some characterizations Math.
ar-
J. 4, 527-618.
of locally
resistant
BIB designs
of degree one. Ann.
Inst.
A 39, 661-669.
Kageyama, S. and G.M. Saha (1987). On resistant t-designs. Ars Combinaf. 23, 81-92. Most, B.M. (1975). Resistance of balanced incomplete block designs. Ann. Statist. 3, 1149-l 162. Shah, S.M. and C.C. B 39, 406-408. Shah,
Gujarathi
S.M. and C.C. Gujarathi
B 45, 225-232.
(1977). On a locally (1983). Resistance
resistant
of balanced
BIB design of degree one. Sankhya incomplete
block designs.
Sankhyo
Ser. Ser.
of Statistical
Planning
and Inference
27 (1991) 263-269
263
North-Holland
Resistance of block designs Rajeshwar
Singh
Department of Statistics, Institute of Advanced Studies, Meerut University, Meerut, India
V.K.
Gupta
Indian Agricultural Statistics Research Institute, New Delhi 110012, India Received
14 December
Recommended
1988; revised
by AS.
manuscript
received
(1974) introduced
resistant
Abstract: Hedayat
and
designs.
were essentially
degree
The results
one. This paper
well as universally resistant
designs
23 February
1990
Hedayat
John extends
optimal of degree
on locally/globally
the concept
of resistance
block designs with unequal
and susceptible resistant
balanced
to general
variance
balanced
incomplete
block
incomplete
block designs
of
balanced
block designs
as
block sizes. Some methods
of constructing
locally
one have been given.
AMS Subject Classification: Primary Key words and phrases: Resistant
62KlO;
designs;
secondary
variance
05B05.
balanced
designs;
universally
optimal
designs.
1. Introduction Consider a block design d in b blocks, u treatments and u x b incidence matrix Nd = (nd$, where ndi; is the replication number of the i-th treatment in the j-th blockofd,i=l,..., ; , . . . , b. The row and column sums of Nd are respectively the elements of Yd =‘;r”= d,,..’.,rd")' and kd = (k,, 1.. , I$,)‘. Further, let R, = diag (l;di, . . . , r&,)
and
& = diag (kdi, . . . , k&).
Under the usual homoscedastic, fixed effects, additive model, the coefficient matrix of the reduced normal equations for estimating the linear functions of treatment effects is c,=R,-N,K,-‘h$.
(1.1)
We shall deal only with connected designs throughout this paper. For definitions and some notations reference may be made to Kageyama (1987). Hedayat and John (1974) introduced and studied resistant balanced incomplete block (BIB) designs. Other results concerning resistance of BIB designs known so far are those given by Most (1975), Shah and Gujarathi (1977, 1983), Chandak 0378-3758/91/$03.50
0
1991-Elsevier
Science
Publishers
B.V. (North-Holland)
264
R. Singh,
V.K.
Gupta / Resistance
of block designs
(1980), Kageyama (1982, 1987) and Kageyama and Saha (1987). Kageyama (1987) proposed the idea of investigating resistant variance balanced designs. Such examples are found in Kageyama (1974, 1976). The purpose of this article is to study locally resistant variance balanced block designs. In Section 2, we study the characterization and construction of locally resistant variance balanced designs of degree one. This article also proposes to extend the concept of local resistance to universally optimal block designs. Pal and Pal (1987) studied the universal optimality of nonproper variance balanced designs in the class of designs D(o; b; k,, . . . , kb), where D(o;b;k,, . ..) kb) denotes the class of all connected designs in o treatments, b blocks and fixed block sizes k ,, . . . , k,. In Section 3, the concept of locally resistant variance balanced designs is extended to locally resistant universally optimal designs. Some series of resistant universally optimal designs of degree one and more are given. These designs are also locally resistant variance balanced designs. An important point about locally resistant universally optimal designs is that the class of resulting designs is different from the class of original designs. This happens with locally resistant BIB and variance balanced designs also. The original design has u+ 1 treatments while the resulting design has only u treatments and therefore the classes of designs in which the original and the resulting designs are optimal is bound to be different. But what is important is that the optimality is retained in the resulting design after losing information.
2. Resistant
variance
balanced
block designs
This section obtains a necessary and sufficient condition for a variance balanced block design to be resistant of degree one. Without any loss of generality, let Nd, as given in (2.1), be the incidence matrix of a variance balanced design d,
(2.1) It is assumed that the first treatment appears in the first m blocks, p’=@, . . . ,p,J andp’J=r,, where J, is a tx 1 vector of ones. Let k =(k’,,k;) denote the b x 1 vector of block sizes, where k, = (k,, . . . , k,)’ is the m x 1 vector of first m block sizes kb)’ is the (b-m) x 1 vector of the remaining b-m block sizes. and k*=(k,+,,..., Also let k, = k, -p. Similarly r= (r,,r;)’ denotes the u x 1 vector of replication the vector of the last o- 1 replication numbers with r2 = (r2, . . . , ro)’ denoting numbers. We shall denote by R,, K, K,, K2 and JCs diagonal matrices with successive elements of the vectors rz, k, k,, k2 and k3 on the diagonals respectively. Let 6 (> 0) denote the common value of the off-diagonal elements of N,ZC’Ni. Also denote by
K4 = dM(k, -pJklA
. . . , W,,,-n,&h,J.
265
R. Singh, V.K. Gupta / Resistance of block designs
Then
it is easy to see that
R,-- N,K;‘N;
- N,K;‘N;
= &(I,_,
- JJ’/v).
Let 25 be the design obtained after deleting the first treatment from parameters of a are D= u- 1, 6= 6, ~=r,, k= (k;, ki)’ and incidence NJ= [N,, N2]. The C-matrix of a is Cd= R, - N,K;‘N;
= R, - N,K,‘N;
d. The matrix
- N,KF’N; - N,K,-‘N; - N,K,-‘N;.
It therefore follows that il is variance balanced if and only if N,K;‘N’, = al,_ I + /3JJ’, (x2 0, /I? 0 and cr + (u - l)p= 6. We thus have the following theorem: Theorem
2.1. A necessary and sufficient
design to be resistant cw+(u- l)P=S.
condition for a variance balanced block of degree one is that N,Ki’N’, =aZ,_, +/lJJ’, with
Remark 2.1. The above theorem gives a mathematical characterization of locally resistant variance balanced designs in terms of N,. It would be interesting to get this in terms of design parameters, but it does not appear to be possible. We now give some methods designs of degree one.
of constructing
locally
resistant
variance
balanced
2.1. Forpositive integers p, n and m =p(n + l)/@ + 1) there exists a locally resistant variance balanced design of degree one with parameters v= n + 2, b = m + n + 1, r = ((n + l),(m +p)JL +,)‘, k = ((n + l)J&,(p + 1)JA + i)’ and incidence matrix
Method
0; J’,
Nd=
(2.2)
i J,Jin Proof.
Removing N, =
1)=6
0,
the first treatment
oil PZ,
K,=P(P+ and cx+p(u-
PZ,,
from d gives
P 0, 1 ’ ~)Z,,+I,
WG’N’,=b’t~+1)1~,+~,
for cr=6=p/(p+
1) and p=O.
2.2. Let Nd be the incidence matrix of a variance balanced block design d with parameters v, b, r and k and common value of the off-diagonal elements of
Method
266
R. Singh, V.K. Gupta / Resistance
of block designs
- Cd matrix of Nd as 6. Then for any integer a (2 0), there exists a locally resistant variance balanced design d * of degree one with incidence matrix N$=
0; . . . 0; Nd . . . Nd ” /
I,
(a + l)JL I,+aJJ’ 1
m times b*=bm+v,
and parameters v *=v+l, r*=(v(a+
l), mr’+(av+
k*=(k’, . . . . k’, (au + a + 2)JI)‘,
l)J’)‘,
if ma= (a(vProof.
Removing
1)+2)-l.
l)+ l}{a(v+
from d* gives
the first treatment
N, = I, + aJJ’,
K4 = { t/(a + 1)}1,,
= {(a+ l>/t}{Z,+
N,K:‘N;
(a2v+ 2a)JJ’},
Example
2.1.
j? = (a2v +-2a)(a + 1)/t.
a=(a+ 1)/t,
t = (au + a + 2)(av + l), Let Nd be a BIB design
with parameters
v = 6, b = 10, r= 5, k = 3,
L=2. Then for a= 1, Nd*=
06 Nd
2 J; Z,+JJ
I
is the incidence matrix of a locally resistant with respect to the first treatment.
variance
balanced
design of degree one
Method 2.3. Consider a BIB design d, with parameters v’, b’= v’(v’- 1)/k, r’ = v’- 1, k, A’ = k - 1 and incidence matrix N. Then there exists a locally resistant variance balanced design d * of degree one with parameters v = VI+ 1, b = b’+ v’,
r = ((r’+ k - l)JI,v’)‘, k = kJb and incidence matrix
Np=
Proof.
On
N o;,
removing
K4 = k(k - l)Z,,, and (k-1)/k and a=O.
(k - l)Z,, J;,
1.
(2.3)
the v-th treatment from d*, we have N1 = (k- l)I,,, N,K;‘N; = [(k - l)/k]I,. Also (Y+/3(0 - 1) = 6 for a = 6 =
We now give some series of BIB designs
dl used in the method
just described.
R. Singh, V.K. Gupta / Resistance of block
designs
(i) If tk+ 1 is a prime or prime power and x is a primitive root of GF(tk+ then the t initial sets (2, A!+‘, . . . ,2”‘k- ‘)(), i=O, 1, . . . , t - 1, form a difference
261
l), set
for a BIB design with parameters u = tk+ 1, b = t(tk+ l), r= tk, k, A = k - 1. (ii) If 4t- 1 is a prime or a prime power and x is a primitive root of GF(4tl), then the initial sets (0, 2, 2,. . . ,x4”- “), (03, x, 2, . . . ,x~‘-~) form a difference set of a BIB design with the parameters u=4t, b=2(4t- l), r=4t- 1, k=2t, A=2t- 1.
3. Resistance
of optimal
designs
This section studies the resistance of universally optimal block designs. If a universally optimal design d belonging to certain class D remains invariant under loss or deletion of some (or any) t treatments then d is said to be locally (globally) resistant of degree t. The design d is invariant if the resulting design obtained upon deleting or losing t treatments remains universally optimal over a certain class. Example 3.1. and incidence
Consider matrix
a design with parameters
u = 8, b = 14, r= 14, k = (12J;,4J;)
21112120111010 22111210011101 12211121001110
Nd=
21221110100111 12122111010011 11212211101001 11121221110100 22222220000000
This design is universally optimal over D(8; 14; 12&4J;). It is locally resistant of degree one with respect to the last treatment because the design obtained after deleting the last treatment is also universally optimal over D(7; 14; lOJ;,4J;). We now have the following
results:
The existence of a BIB design d with parameters v, b, r, k, A such that b f 21= 3r and incidence matrix Nd implies the existence of a locally resistant universally optimal design d * of degree one and parameters v * = v + 1, b * = 2b, r*=2b 9 Theorem
3.1.
k*= [(u+k+2)J;, and incidence matrix
(u-k)Jh]‘,
268
R. Singh,
V.K. Gupta / Resistance of block designs
where fid = J,,Jh - Nd. Proof. The proof follows by noting that the design obtained treatment is universally optimal over
D(o;b*;{(u+k)J;, For BIB designs satisfying John (1974, p. 154).
after deleting
the last
(u-k)J;)‘). b + 2A = 3r, reference
may be made to Hedayat
and
3.2. The existence of a symmetric BIB design d with parameters v = b, r = k, A and incidence matrix Nd implies the existence of a locally resistant universally optimal design d* of degree k or u - k and parameters o * = v, b * = b + t, Theorem
r*=(r+ab+st)J,,,
k * = [(k + au)Jb, suJi] ’
and incidence matrix Nd* = [Nd + aJ,Jb
sJ,J;].
Proof. It is easy to verify that the design d* is universally optimal over consider the first column of D(v*; b*;k;: . . . . k,*,). Without any loss of generality, N& Delete from Nd* the k treatments corresponding to the element one in the first column of N& It is known that if we delete any k treatments which appear in the same block of a symmetric BIB design then the resulting design is BIB with parameters u, = u-k, b, = u - 1, r, = k, k, = k - A, A. Using this fact it follows that optimal over D(u- k, b*, k**) where the resulting design d ** is universally
k,**= i
a(u - k) k-A+a(u-k) s(u - k)
ifj=l, ifj=2,...,b, ifj=b+ l,...,b*.
The design d** is therefore locally resistant of degree k. SimilarIy if we delete the u-k treatments corresponding to the element zero in the first column of Nd from Nd*, then the resulting design is locally resistant of degree u-k. Remark 3.1. The designs given in Theorems variance balanced designs.
3.1 and 3.2 are also locally
resistant
Acknowledgements The authors are thankful to the referees for their valuable suggestions to a considerable improvement in the presentation of the results.
which led
R. Singh,
V.K. Gupta
/ Resistance
of block designs
269
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