3 Tile Assembly Model (Rothemund, Winfree, Adleman) T = G(y) = 2 G(g) = 2 G(r) = 2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 Tile Set: Glue Function: Temperature: x ed cba
1 David DotyCalifornia Institute of Technology Matthew J.
PatitzUniversity of Texas Pan-American Dustin ReishusUniversity of
Southern California Robert SchwellerUniversity of Texas
Pan-American Scott M. SummersUniversity of Wisconsin-Platteville
FOCS 2010 October 25, 2010 Strong Fault-Tolerance for Self-Assembly
with Fuzzy Temperature 2 Outline Basic Tile Assembly Model Fuzzy
Fault Tolerance Efficient, Fault Tolerant Results 3 Tile Assembly
Model (Rothemund, Winfree, Adleman) T = G(y) = 2 G(g) = 2 G(r) = 2
G(b) = 2 G(p) = 1 G(w) = 1 t = 2 Tile Set: Glue Function:
Temperature: x ed cba 4 T = G(y) = 2 G(g) = 2 G(r) = 2 G(b) = 2
G(p) = 1 G(w) = 1 t = 2 d e x ed cba Tile Assembly Model
(Rothemund, Winfree, Adleman) 5 T = G(y) = 2 G(g) = 2 G(r) = 2 G(b)
= 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba Tile Assembly Model
(Rothemund, Winfree, Adleman) 6 T = G(y) = 2 G(g) = 2 G(r) = 2 G(b)
= 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba bc Tile Assembly Model
(Rothemund, Winfree, Adleman) 7 T = G(y) = 2 G(g) = 2 G(r) = 2 G(b)
= 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba bc Tile Assembly Model
(Rothemund, Winfree, Adleman) 8 T = G(y) = 2 G(g) = 2 G(r) = 2 G(b)
= 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba bc Tile Assembly Model
(Rothemund, Winfree, Adleman) 9 T = G(y) = 2 G(g) = 2 G(r) = 2 G(b)
= 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba bca Tile Assembly Model
(Rothemund, Winfree, Adleman) 10 T = G(y) = 2 G(g) = 2 G(r) = 2
G(b) = 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba bca Tile Assembly
Model (Rothemund, Winfree, Adleman) 11 T = G(y) = 2 G(g) = 2 G(r) =
2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba bca Tile Assembly
Model (Rothemund, Winfree, Adleman) 12 T = G(y) = 2 G(g) = 2 G(r) =
2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 d e x ed cba bca Tile Assembly
Model (Rothemund, Winfree, Adleman) 13 T = G(y) = 2 G(g) = 2 G(r) =
2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 x ed cba abc d e Tile Assembly
Model (Rothemund, Winfree, Adleman) 14 T = G(y) = 2 G(g) = 2 G(r) =
2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 x ed cba x abc d e Tile Assembly
Model (Rothemund, Winfree, Adleman) 15 T = G(y) = 2 G(g) = 2 G(r) =
2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 abc d e x x ed cba Tile Assembly
Model (Rothemund, Winfree, Adleman) 16 T = G(y) = 2 G(g) = 2 G(r) =
2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 x ed cba abc d e xx Tile
Assembly Model (Rothemund, Winfree, Adleman) 17 T = G(y) = 2 G(g) =
2 G(r) = 2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 x ed cba abc d e xx x
Tile Assembly Model (Rothemund, Winfree, Adleman) 18 T = G(y) = 2
G(g) = 2 G(r) = 2 G(b) = 2 G(p) = 1 G(w) = 1 t = 2 x ed cba abc d e
xx xx Tile Assembly Model (Rothemund, Winfree, Adleman) 19 Outline
Basic Tile Assembly Model Errors! Fuzzy Fault Tolerance Efficient,
Fault Tolerant Results ideal cooperative binding: tile attaches to
assembly if and only if it interacts with strength 2 (such as two
matching strength-1 glues) stable at temperature 1 = temporarily
stable at temperature 2 stable at temperature 2 but not producible
at temperature 2 a bd a x c a x c a bd a bd a x c c d c d more
realistic kinetic model: tile attaches to assembly but detaches
"quickly" if attached with only strength 1 (and detaches "slowly"
if attached with strength 2) insufficient attachment... becomes
stabilized by subsequent attachment: permanent error! 22 Outline
Basic Tile Assembly Model Errors! Fuzzy Fault Tolerance Efficient,
Fault Tolerant Results Dependably producible (DP): the set of
supertiles that can be assembled at temperature = 2 abc d e xx abc
d e xx xx d e x b Dependably producible (DP): the set of supertiles
that can be assembled at temperature = 2 Dependably terminal (DT):
the subset of DP supertiles that are terminal at temperature = 2
abc d e xx abc d e xx xx d e x b abc d e xx xx Dependably
producible (DP): the set of supertiles that can be assembled at
temperature = 2 Dependably terminal (DT): the subset of DP
supertiles that are terminal at temperature = 2 Plausibly
producible (PP): the set of supertiles that can be assembled at
temperature = 1 abc d e xx abc d e xx xx d e x b abc d e xx xx abc
d e xx xx xxxx abc d e xx xx xxxxxxxx Dependably producible (DP):
the set of supertiles that can be assembled at temperature = 2
Dependably terminal (DT): the subset of DP supertiles that are
terminal at temperature = 2 Plausibly producible (PP): the set of
supertiles that can be assembled at temperature = 1 Plausibly
stable (PS): the set of supertiles in PP that are stable at
temperature = 2 abc d e xx abc d e xx xx d e x b abc d e xx xx abc
d e xx xx xxxx abc d e xx xx xxxxxxxx abc d e xx xx xxxxxxxx The
Fuzzy Temperature Fault-Tolerance Design Problem Given a target
shape X, design a tile set such that: Every PS supertile can grow
into a DT supertile Every DT supertile has the shape X Tile set
Desired shape Avoid this: 28 Goal: Design an efficient tile system
for the assembly of a n x n square that is fuzzy fault tolerant.
Result: O(log n) tile complexity construction for n x n squares
that is fuzzy fault tolerant. 29 T = G(y) = 2 G(g) = 2 G(r) = 2
G(b) = 2 G(p) = 1 G(w) = 1 t = 2 x ed cba abc d e xx xx Square
Building 30 Square Building: Normal Approach n 31 Square Building x
Tile Complexity: 2n n Square Building 0000 log n -Use log n tile
types to seed counter: Square Building 0000 log n -Use 8 additional
tile types capable of binary counting: -Use log n tile types
capable of Binary counting: Square Building 0000 log n Use 8
additional tile types capable of binary counting: -Use log n tile
types capable of Binary counting: Square Building Use 8 additional
tile types capable of binary counting: -Use log n tile types
capable of Binary counting: log n Square Building Use 8 additional
tile types capable of binary counting: -Use log n tile types
capable of Binary counting: Square Building n log n log n x y Tile
Complexity: O(log n) (Rothemund, Winfree 2000) A Fuzzy Fault
Tolerant Counter? A counter seems important for efficient assembly
of n x n squares Current counter constructions are not fuzzy fault
tolerant c c 0 1 nc 1 n 0 01 nn n n 0 1 [Barish, Shulman,
Rothemund, Winfree, 2009] 40 Outline Basic Tile Assembly Model
Errors! Fuzzy Fault Tolerance Efficient, Fault Tolerant Results
Strength-2 growth is error-free Idea: use nondeterministic
strength-2 growth to guess numbers in counter and use geometric
blocking (steric hindrance) to ensure they only come together in
proper places. Strength-1 bonds used to enforce bumps are present
when binding occurs Strength-2 bondsStrength-1 bonds Previous Tile
Set Not Fault Tolerant Producible at temperature 1 but stable (and
erroneous) at temperature 2 Add more synchronization Each counter
column is composed of 2 sub-columns, each which contributes a
single strength bond at the top. Each must be fully complete for
them to bind. Strength-1 glue Strength-2 glue Fuzzy Temperature
Fault-Tolerant Counter Square Composed of One Horizontal Counter
and Multiple Copies of Vertical Counter Open Problems Make
construction robust to non-rigidity of DNA tiles to enhance
effectiveness of programmed steric hindrance Experimentally
determine the largest size of supertiles that reliably attach
Universal Computation and Fuzzy-Fault Tolerance? Assembly Time
