5

Heres a block of code that plots a function over a range, as well as the at a single input :

a = 1.0
f(x::Float64) = -x^2 - a
scatter(f, -3:.1:3)
scatter!([a], [f(a)])

enter image description here

i would like to plot the line, tangent to the point, like so:

enter image description here

Is there a pattern or simple tool for doing so?

3 Answers 3

5

That depends on what you mean by "pattern or simple tool" - the easiest way is to just derive the derivative by hand and then plot that as a function:

hand_gradient(x) = -2x

and then add plot!(hand_gradient, 0:0.01:3) to your plot.

Of course that can be a bit tedious with more complicated functions or when you want to plot lots of gradients, so another way would be to utilise Julia's excellent automatic differentiation capabilities. Comparing all the different options is a bit beyond the scope of this answer, but check out https://juliadiff.org/ if you're interested. Here, I will be using the widely used Zygote library:

julia> using Plots, Zygote

julia> a = 1.0;

julia> f(x) = -x^2 - a;

[NB I have slightly amended your f definition to be in line with the plot you posted, which is an inverted parabola]

note that here I am not restricting the type of input argument x to f - this is crucial for automatic differentiation to work, as it is implemented by runnning a different number type (a Dual) through your function. In general, restricting argument types in this way is an anti-pattern in Julia - it does not help performance, but makes your code less interoperable with other parts of the ecosystem, as you can see here if you try to automatically differentiate through f(x::Float64).

Now let's use Zygote to provide gradients for us:

julia> f'
#43 (generic function with 1 method)

as you can see, running f' now returns an anonymous function - this is the derivative of f, as you can verify by evaluating it at a specific point:

julia> f'(2)
-4.0

Now all we need to do is leverage this to construct a function that itself returns a function which traces out the line of the gradient:

julia> gradient_line(f, x₀) = (x -> f(x₀) + f'(x₀)*(x-x₀))
gradient_line (generic function with 1 method)

this function takes in a function f and a point x₀ for which we want to get the tangent, and then returns an anonymous function which returns the value of the tangent at each value of x. Putting this to use:

julia> default(markerstrokecolor = "white", linewidth = 2);

julia> scatter(f, -3:0.1:3, label = "f(x) = -x² - 1", xlabel = "x", ylabel = "f(x)");

julia> scatter!([1], [f(1)], label = "", markersize = 10);

julia> plot!(gradient_line(f, 1), 0:0.1:3, label = "f'(1)", color = 2);

julia> scatter!([-2], [f(-2)], label = "", markersize = 10, color = 3);

julia> plot!(gradient_line(f, -2), -3:0.1:0, label = "f'(-2)", color = 3)

enter image description here

3
  • thats rad you brought out Zygote. . . an ad solution in Julia was exactly the kind of thing im looking for!
    – neutrino
    Feb 17, 2021 at 19:03
  • could you explain gradient_line(f, x₀) = (x -> f(x₀) + f'(x₀)*(x-x₀)) a little more? it looks similar to the limit definition i'm used to seeing, but not quite
    – neutrino
    Feb 23, 2021 at 15:15
  • It's just a straight line with an intercept at point x₀ and a slope of f'(x₀) - essentially your usual y = a + bx where a is the value of the actual function at the point x₀ through which we want the line to pass, b is the derivative of the function at that point, and the "x" in y=a+bx is replaced by x-x₀ because our "origin" is the point at which we're taking the tangent.
    – Nils Gudat
    Feb 23, 2021 at 17:00
4

It is overkill for this problem, but you could use the CalculusWithJulia package which wraps up a tangent operator (along with some other conveniences) similar to what is derived in the previous answers:

using CalculusWithJulia # ignore any warnings 
using Plots
f(x) = sin(x)
a, b = 0, pi/2
c = pi/4
plot(f, a, b)
plot!(tangent(f,c), a, b)
3

Well, the tool is called high school math :)

You can simply calculate the slope (m) and intersect (b) of the tanget (mx + b) and then plot it. To determine the former, we need to compute the derivative of the function f in the point a, i.e. f'(a). The simplest possible estimator is the difference quotient (I assume that it would be cheating to just derive the parabola analytically):

m = (f(a+Δ) - f(a))/Δ

Having the slope, our tanget should better go through the point (a, f(a)). Hence we have to choose b accordingly as:

b = f(a) - m*a

Choosing a suitably small value for Δ, e.g. Δ = 0.01 we obtain:

Δ = 0.01
m = (f(a+Δ) - f(a))/Δ
b = f(a) - m*a

scatter(f, -3:.1:3)
scatter!([a], [f(a)])
plot!(x -> m*x + b, 0, 3)

plotwithtangent

Higher order estimators for the derivative can be found in FiniteDifferences.jl and FiniteDiff.jl for example. Alternatively, you could use automatic differentiation (AD) tools such as ForwardDiff.jl to obtain the local derivative (see Nils answer for an example).

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