Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 David DotyCalifornia Institute of Technology Matthew J. PatitzUniversity of Texas Pan-American Dustin ReishusUniversity of Southern California Robert.

Published byAnna Poole Modified over 9 years ago

Similar presentations

Presentation on theme: "1 David DotyCalifornia Institute of Technology Matthew J. PatitzUniversity of Texas Pan-American Dustin ReishusUniversity of Southern California Robert."— Presentation transcript:

1 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 2 Outline Basic Tile Assembly Model Fuzzy Fault Tolerance Efficient, Fault Tolerant Results

3 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 19 Outline Basic Tile Assembly Model Errors! Fuzzy Fault Tolerance Efficient, Fault Tolerant Results

20 ideal cooperative binding: tile attaches to assembly if and only if it interacts with strength ≥ 2 (such as two matching strength-1 glues)

21 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 22 Outline Basic Tile Assembly Model Errors! Fuzzy Fault Tolerance Efficient, Fault Tolerant Results

23  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

24  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

25  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

26  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

27 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 01 2 1 2 0 1 2 1 2 01 2 1 2 Tile set Desired shape Avoid this:

28 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 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 30 Square Building: Normal Approach n

31 31 Square Building x Tile Complexity: 2n n

32 Square Building 0000 log n -Use log n tile types to seed counter:

33 Square Building 0000 log n -Use 8 additional tile types capable of binary counting: -Use log n tile types capable of Binary counting:

34 Square Building 0000 log n 000 00 000 1010 1100 1110 000 01 10 1 1 11 1 0001 -Use 8 additional tile types capable of binary counting: -Use log n tile types capable of Binary counting:

35 Square Building 0000 000 000 00 000 1010 1100 1110 0001 0011 0101 0111 1001 1011 1111 1101 1 1 11 1 -Use 8 additional tile types capable of binary counting: -Use log n tile types capable of Binary counting: log n

36 Square Building 0000 000 000 00 000 1010 1100 1110 0001 0011 0101 0111 1001 1011 1111 1101 1 1 11 1 0 0 0 0 1 0 0 0 0 1 0 0 1 1 0 0 0 0 1 0 1 0 1 0 0 1 1 0 1 1 1 0 0 0 0 1 1 0 0 1 0 1 0 1 1 1 0 1 0 0 1 1 1 0 1 1 0 1 1 1 1 1 1 1 -Use 8 additional tile types capable of binary counting: -Use log n tile types capable of Binary counting:

37 Square Building 0000 000 000 00 000 1010 1100 1110 0001 0011 0101 0111 1001 1011 1111 1101 1 1 11 1 0 0 0 0 1 0 0 0 0 1 0 0 1 1 0 0 0 0 1 0 1 0 1 0 0 1 1 0 1 1 1 0 0 0 0 1 1 0 0 1 0 1 0 1 1 1 0 1 0 0 1 1 1 0 1 1 0 1 1 1 1 1 1 1 n – log n log n x y Tile Complexity: O(log n) (Rothemund, Winfree 2000)

38 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 0001 0 0000 10 c 000 10 c 0 1 nc 1 n 0 01 nn n n 0 1

39 [Barish, Shulman, Rothemund, Winfree, 2009]

40 40 Outline Basic Tile Assembly Model Errors! Fuzzy Fault Tolerance Efficient, Fault Tolerant Results

41 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

42 Previous Tile Set Not Fault Tolerant Producible at temperature 1 but stable (and erroneous) at temperature 2

43 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

44 Fuzzy Temperature Fault-Tolerant Counter

45 Square Composed of One Horizontal Counter and Multiple Copies of Vertical Counter

46 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

Download ppt "1 David DotyCalifornia Institute of Technology Matthew J. PatitzUniversity of Texas Pan-American Dustin ReishusUniversity of Southern California Robert."

Similar presentations

Ashish Goel, 1 A simple analysis Suppose complementary DNA strands of length U always stick, and those of length L never stick (eg:

Ashish Goel, 1 A simple analysis Suppose complementary DNA strands of length U always stick, and those of length L never stick (eg:
Tile Complexity of Assembly of Fixed Size Rows and Squares by John Reif and Harish Chandran.

Tile Complexity of Assembly of Fixed Size Rows and Squares by John Reif and Harish Chandran.
Strict Self-Assembly of Discrete Sierpinski Triangles James I. Lathrop, Jack H. Lutz, and Scott M. Summers Iowa State University © James I. Lathrop, Jack.

Strict Self-Assembly of Discrete Sierpinski Triangles James I. Lathrop, Jack H. Lutz, and Scott M. Summers Iowa State University © James I. Lathrop, Jack.
1 Thirteenth International Meeting on DNA Computers June 5, 2007 Staged Self-Assembly: Nanomanufacture of Arbitrary Shapes with O(1) Glues Eric DemaineMassachusetts.

1 Thirteenth International Meeting on DNA Computers June 5, 2007 Staged Self-Assembly: Nanomanufacture of Arbitrary Shapes with O(1) Glues Eric DemaineMassachusetts.
Active Tile Self Assembly: Daria Karpenko Department of Mathematics and Statistics, University of South Florida Simulating Cellular Automata at Temperature.

Active Tile Self Assembly: Daria Karpenko Department of Mathematics and Statistics, University of South Florida Simulating Cellular Automata at Temperature.
Alternative Tile Assembly Models and Complexity Results Tianqi Song.

Alternative Tile Assembly Models and Complexity Results Tianqi Song.
An information-bearing seed for nucleating algorithmic self-assembly Presented by : Venkata Chaitanya Goli 651366318 Robert D. Barish1, Rebecca Schulman1,

An information-bearing seed for nucleating algorithmic self-assembly Presented by : Venkata Chaitanya Goli Robert D. Barish1, Rebecca Schulman1,
Self-Assembly with Geometric Tiles ICALP 2012 Bin FuUniversity of Texas – Pan American Matt PatitzUniversity of Arkansas Robert Schweller (Speaker)University.

Self-Assembly with Geometric Tiles ICALP 2012 Bin FuUniversity of Texas – Pan American Matt PatitzUniversity of Arkansas Robert Schweller (Speaker)University.
1 SODA January 23, 2011 Temperature 1 Self-Assembly: Deterministic Assembly in 3D and Probabilistic Assembly in 2D Matthew CookUniversity of Zurich and.

1 SODA January 23, 2011 Temperature 1 Self-Assembly: Deterministic Assembly in 3D and Probabilistic Assembly in 2D Matthew CookUniversity of Zurich and.
Paul Rothemund, Departments of Computer Science and Computation & Neural Systems, California Institute of Technology Jerzy Szablowski 20.309: Biological.

Paul Rothemund, Departments of Computer Science and Computation & Neural Systems, California Institute of Technology Jerzy Szablowski : Biological.
The Power of Seeds in Tile Self-Assembly Andrew Winslow Department of Computer Science, Tufts University.

The Power of Seeds in Tile Self-Assembly Andrew Winslow Department of Computer Science, Tufts University.
Design of a Minimal System for Self-replication of Rectangular Patterns of DNA Tiles Vinay K Gautam 1, Eugen Czeizler 2, Pauline C Haddow 1 and Martin.

Design of a Minimal System for Self-replication of Rectangular Patterns of DNA Tiles Vinay K Gautam 1, Eugen Czeizler 2, Pauline C Haddow 1 and Martin.
Self-Assembly Ho-Lin Chen Nov 8 2005. 2 Self-Assembly is the process by which simple objects autonomously assemble into complexes. Geometry, dynamics,

Self-Assembly Ho-Lin Chen Nov Self-Assembly is the process by which simple objects autonomously assemble into complexes. Geometry, dynamics,
Reducing Tile Complexity for Self-Assembly Through Temperature Programming Midwest Theory Day, December 10, 2006 Based on paper to appear in SODA 2006.

Reducing Tile Complexity for Self-Assembly Through Temperature Programming Midwest Theory Day, December 10, 2006 Based on paper to appear in SODA 2006.
Complexities for Generalized Models of Self-Assembly Gagan Aggarwal Stanford University Michael H. Goldwasser St. Louis University Ming-Yang Kao Northwestern.

Complexities for Generalized Models of Self-Assembly Gagan Aggarwal Stanford University Michael H. Goldwasser St. Louis University Ming-Yang Kao Northwestern.
DNA Computing by Self Assembly  Erik Winfree, Caltech.

DNA Computing by Self Assembly  Erik Winfree, Caltech.
Robust Self-Assembly of DNA Eduardo Abeliuk Dept. of Electrical Engineering Stanford University November 30, 2006.

Robust Self-Assembly of DNA Eduardo Abeliuk Dept. of Electrical Engineering Stanford University November 30, 2006.
Complexities for Generalized Models of Self-Assembly Gagan Aggarwal Stanford University Michael H. Goldwasser St. Louis University Ming-Yang Kao Northwestern.

Complexities for Generalized Models of Self-Assembly Gagan Aggarwal Stanford University Michael H. Goldwasser St. Louis University Ming-Yang Kao Northwestern.
Reducing Tile Complexity for Self-Assembly Through Temperature Programming Symposium on Discrete Algorithms SODA 2006 January 23, 2006 Robert Schweller.

Reducing Tile Complexity for Self-Assembly Through Temperature Programming Symposium on Discrete Algorithms SODA 2006 January 23, 2006 Robert Schweller.
Ashish Goel Stanford University Joint work with Len Adleman, Holin Chen, Qi Cheng, Ming-Deh Huang, Pablo Moisset, Paul.

Ashish Goel Stanford University Joint work with Len Adleman, Holin Chen, Qi Cheng, Ming-Deh Huang, Pablo Moisset, Paul.

Similar presentations

Ads by Google