{Use of Tech} Difference quotients Suppose f is differentiable for all x and consider the function D(x) = f(x+0.01)-f(x) / 0.01 For the following functions, graph D on the given interval, and explain why the graph appears as it does. What is the relationship between the functions f and D?
f(x) = sin x on [−π,π]

A function is differentiable at a point if it has a defined derivative at that point, meaning the function's graph has a tangent line at that point. This implies that the function is continuous and does not have any sharp corners or vertical tangents. Differentiability is crucial for understanding how functions change and is foundational for concepts like the difference quotient.

The difference quotient is a formula used to approximate the derivative of a function at a point. It is defined as D(x) = (f(x + h) - f(x)) / h, where h is a small increment. In this case, h is set to 0.01, allowing us to analyze the average rate of change of the function f over a small interval, which approaches the instantaneous rate of change as h approaches zero.

Graphing the function D(x) allows us to visualize how the average rate of change of f(x) behaves over the interval. The shape of the graph of D will reflect the slope of the tangent line to f(x) at various points, illustrating how the derivative of f relates to the values of D. This relationship helps in understanding the behavior of f and its rate of change across the specified interval.