Following table shows the calculations:
| X | Y | X^2 | Y^2 | XY | |
| 35 | -0.56 | 1225 | 0.3136 | -19.6 | |
| 40 | -0.65 | 1600 | 0.4225 | -26 | |
| 45 | -1.16 | 2025 | 1.3456 | -52.2 | |
| 50 | -1.21 | 2500 | 1.4641 | -60.5 | |
| 55 | -1.97 | 3025 | 3.8809 | -108.35 | |
| 60 | -2.87 | 3600 | 8.2369 | -172.2 | |
| 65 | -3.09 | 4225 | 9.5481 | -200.85 | |
| 70 | -3.21 | 4900 | 10.3041 | -224.7 | |
| 75 | -3.93 | 5625 | 15.4449 | -294.75 | |
| 80 | -4.21 | 6400 | 17.7241 | -336.8 | |
| Total | 575 | -22.86 | 35125 | 68.6848 | -1495.95 |

Answer: The requried correlation coefficient is -0.9861.
also given are the products of the stimulus intensities and Weber fractions for each of the...
Weber's law, a concept taught in most Introduction to Psychology courses, states that the ratio of the intensity of a stimulus to the "just noticeable" increment in intensity is constant, that is, the ratio doesn't depend on the intensity of the stimulus. The ratio is called the "Weber fraction," so a concise statement of Weber's law is that "the Weber fraction is constant, regardless of the stimulus intensity." It turns out that Weber's law is not so much a law...