This week the #puzzle is: Can You Power up the Hill? #trigonometry #root
| … we’ll be looking at a model for a cyclist’s speed v as a function of their pedaling power P, their mass m, and the ground’s angle of inclination 𝜃: |
| (For the purposes of this puzzle, you needn’t worry about the units for power, mass, or speed. If you’re curious, they’re typically given in Watts, kilograms, and kilometers per hour or miles per hour, respectively.) |
| In cycling, roads are marked with a gradient g, which is a hill’s slope, typically expressed as a percentage. Thus, an incredibly steep 45-degree incline has a gradient of 1, or “100 percent.” |
| Consider the following two riders: |
| – A “climber,” who has a power of 300 and a mass of 60 – A “sprinter,” who has a power of 325 and a mass of 80 |
| At what gradient will the climber and sprinter cycle at the same speed? (You can give your answer as a value between 0 and 1 or as a percentage.) |
And for extra credit:
| The climber and the sprinter are racing up a perfectly sinusoidal hill. They go from the base, where the gradient is 0 percent, to the peak, where the gradient is again 0 percent. For them to reach the top at the same time, what should the maximum gradient of the hill be? (You can give your answer as a value between 0 and 1 or as a percentage.) |
| Importantly, note that the formula for v given above is for a rider’s speed along the ground. Thus, when the ground is inclined, the same speed will cover less horizontal distance per unit time. |

Solution, possibly incorrect:
I create 2 graphs, 1 for each rider. The x axis is the angle of the slope, y is the speed. Then I note where the graphs cross.
Result: A slope of 0.055584. This gives both riders a speed of 22.5.
The slope corresponds to a gradient of 0.0556413145901. Let’s say 0.05564 = 5.564%.
And for extra credit:
Something with trigonometry? Maybe an integral? I think I need a reverse function, going from gradient to slope, and I don’t quite see how to do that. Sigh.

































