Difference between revisions of "Chapter 1"
Jump to navigation
Jump to search
| Line 1: | Line 1: | ||
Problems | Problems | ||
| − | + | :[[1.1]]. Show that ''a'' + ''b'' can be less than ''min(a, b)''. | |
| − | |||
| − | + | :1.2. Show that ''a'' × ''b'' can be less than ''min(a, b)''. | |
| − | |||
| − | + | :[[1.3]]. Design/draw a road network with two points ''a'' and ''b'' such that the fastest route between ''a'' and ''b'' is not the shortest route. | |
| − | |||
| − | + | :1.4. Design/draw a road network with two points ''a'' and ''b'' such that the shortest route between ''a'' and ''b'' is not the route with the fewest turns. | |
| − | |||
| − | + | :[[1.5]]. The ''knapsack problem'' is as follows: given a set of integers ''S'' = {''s1, s2. . . , sn}''}, and a target number ''T'', find a subset of ''S'' that adds up exactly to ''T''. For example, there exists a subset within ''S'' = {1, 2, 5, 9, 10} that adds up to ''T'' = 22 but not ''T'' = 23. | |
| − | + | :Find counterexamples to each of the following algorithms for the knapsack problem. That is, give an ''S'' and ''T'' where the algorithm does not find a solution that leaves the knapsack completely full, even though a full-knapsack solution exists. | |
| − | + | ::(a) Put the elements of ''S'' in the knapsack in left to right order if they fit, that is, the first-fit algorithm. | |
| − | + | ::(b) Put the elements of ''S'' in the knapsack from smallest to largest, that is, the best-fit algorithm. | |
| − | + | ::(c) Put the elements of ''S'' in the knapsack from largest to smallest. | |
| − | |||
| − | + | :1.6 | |
| − | + | :[[1.7]] | |
| − | + | :1.8 | |
| − | + | :[[1.9]] | |
| − | + | :1.10 | |
| − | + | :[[1.11]] | |
| − | + | :1.12 | |
| − | + | :[[1.13]] | |
| − | + | :1.14 | |
| − | + | :[[1.15]] | |
| − | + | :1.16 | |
| − | + | :[[1.17]] | |
| − | + | :1.18 | |
| − | + | :[[1.19]] | |
| − | + | :1.20 | |
| − | + | :[[1.21]] | |
| − | + | :1.22 | |
| − | + | :[[1.23]] | |
| − | + | :1.24 | |
| − | + | :[[1.25]] | |
| − | + | :1.26 | |
| − | + | :[[1.27]] | |
| − | + | :1.28 | |
| − | + | :[[1.29]] | |
| + | |||
| + | :1.30 | ||
| + | |||
| + | :[[1.31]] | ||
| + | |||
| + | :1.32 | ||
| + | |||
| + | :[[1.33]] | ||
| + | |||
| + | :1.34 | ||
| + | |||
| + | :[[1.35]] | ||
| + | |||
| + | :1.36 | ||
| + | |||
| + | :[[1.37]] | ||
| + | |||
| + | :1.38 | ||
Back to [[Problem Solutions]] | Back to [[Problem Solutions]] | ||
Revision as of 19:20, 23 August 2020
Problems
- 1.1. Show that a + b can be less than min(a, b).
- 1.2. Show that a × b can be less than min(a, b).
- 1.3. Design/draw a road network with two points a and b such that the fastest route between a and b is not the shortest route.
- 1.4. Design/draw a road network with two points a and b such that the shortest route between a and b is not the route with the fewest turns.
- 1.5. The knapsack problem is as follows: given a set of integers S = {s1, s2. . . , sn}}, and a target number T, find a subset of S that adds up exactly to T. For example, there exists a subset within S = {1, 2, 5, 9, 10} that adds up to T = 22 but not T = 23.
- Find counterexamples to each of the following algorithms for the knapsack problem. That is, give an S and T where the algorithm does not find a solution that leaves the knapsack completely full, even though a full-knapsack solution exists.
- (a) Put the elements of S in the knapsack in left to right order if they fit, that is, the first-fit algorithm.
- (b) Put the elements of S in the knapsack from smallest to largest, that is, the best-fit algorithm.
- (c) Put the elements of S in the knapsack from largest to smallest.
- 1.6
- 1.8
- 1.10
- 1.12
- 1.14
- 1.16
- 1.18
- 1.20
- 1.22
- 1.24
- 1.26
- 1.28
- 1.30
- 1.32
- 1.34
- 1.36
- 1.38
Back to Problem Solutions
