Research Article
Measurement Method of Civil Engineering Complexity Structure Based on Logical Equivalent Model
Table 4
Grid moving algorithm of civil engineering target.
| | Steps | Algorithm tables | Code texts |
| | 1 | The pedestrian updates | Public static void main(String[] args) | | 2 | Target grid is empty | Int abccount = 0; | | 3 | A higher relative probability in | Int spacecount = 0; | | 4 | The same target grid | Int numcount = 0; | | 5 | Pedestrian stands some | Ylabel(‘Amplitude’); | | 6 | A position conflict | Title(‘Output due to weighted input’); | | 7 | Implementation design | Subplot(3, 1, 2) | | 8 | The static field S is | Stem(n, yt); | | 9 | A correspondence between | Ylabel(‘Amplitude’); | | 10 | The move is executed | Title(‘Weighted output: a \cdot y_{1}[n] ‘); | | 11 | During the matching and verification | Subplot(3, 1, 3) | | 12 | Complete verification | Stem(n, d); | | 13 | In some cases | Xlabel(‘Time index n’); ylabel(‘Amplitude’); | | 14 | Achieve complete comparison | Title(‘Difference signal’); | | 15 | This change will be recorded | System.out.println(abccount); | | 16 | Setting file is read | System.out.println(spacecount); | | 17 | Initial comparison | A \cdot x_{1}[n] + b \cdot x_{2}[n]’); | | 18 | All comparison points | System.out.println(othercount); |
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