I am interested in a general root finding problem for an interpolation function.

Suppose I have the following `(x, y)`

data:

```
set.seed(0)
x <- 1:10 + runif(10, -0.1, 0.1)
y <- rnorm(10, 3, 1)
```

as well as a linear interpolation and a cubic spline interpolation:

```
f1 <- approxfun(x, y)
f3 <- splinefun(x, y, method = "fmm")
```

How can I find `x`

-values where these interpolation functions cross a horizontal line `y = y0`

? The following is a graphical illustration with `y0 = 2.85`

.

```
par(mfrow = c(1, 2))
curve(f1, from = x[1], to = x[10]); abline(h = 2.85, lty = 2)
curve(f3, from = x[1], to = x[10]); abline(h = 2.85, lty = 2)
```

I am aware of a few previous threads on this topic, like

- predict x values from simple fitting and annoting it in the plot
- Predict X value from Y value with a fitted model

It is suggested that we simply reverse `x`

and `y`

, do an interpolation for `(y, x)`

and compute the interpolated value at `y = y0`

.

However, this is a bogus idea. Let `y = f(x)`

be an interpolation function for `(x, y)`

, this idea is only valid when `f(x)`

is a monotonic function of `x`

so that `f`

is invertible. Otherwise `x`

is not a function of `y`

and interpolating `(y, x)`

makes no sense.

Taking the linear interpolation with my example data, this fake idea gives

```
fake_root <- approx(y, x, 2.85)[[2]]
# [1] 6.565559
```

First of all, the number of roots is incorrect. We see two roots from the figure (on the left), but the code only returns one. Secondly, it is not a correct root, as

```
f1(fake_root)
#[1] 2.906103
```

is not 2.85.

I have made my first attempt on this general problem at How to estimate x value from y value input after approxfun() in R. The solution turns out stable for linear interpolation, but not necessarily stable for non-linear interpolation. I am now looking for a stable solution, specially for a cubic interpolation spline.

### How can a solution be useful in practice?

Sometimes after a **univariate** linear regression `y ~ x`

or a **univariate** non-linear regression `y ~ f(x)`

we want to backsolve `x`

for a target `y`

. This Q & A is an example and has attracted many answers: Solve best fit polynomial and plot drop-down lines, but none is truly adaptive or easy to use in practice.

- The accepted answer using
`polyroot`

only works for a simple polynomial regression; - Answers using quadratic formula for an analytical solution only works for a quadratic polynomial;
- My answer using
`predict`

and`uniroot`

works in general, but is not convenient, as in practice using`uniroot`

needs interaction with users (see Uniroot solution in R for more on`uniroot`

).

It would be really good if there is an adaptive and easy-to-use solution.