The method `norm.ppf()`

takes a percentage and returns a standard deviation multiplier for what value that percentage occurs at.

It is equivalent to a, 'One-tail test' on the density plot.

From scipy.stats.norm:

*ppf(q, loc=0, scale=1) Percent point function (inverse of cdf — percentiles).*

**Standard Normal Distribution**

The code:

```
norm.ppf(0.95, loc=0, scale=1)
```

Returns a 95% significance interval for a *one-tail test* on a *standard normal distribution* (i.e. a special case of the normal distribution where the mean is 0 and the standard deviation is 1).

**Our Example**

To calculate the value for OP-provided example at which our 95% significance interval lies (For a *one-tail test*) we would use:

```
norm.ppf(0.95, loc=172.7815, scale=4.1532)
```

This will return **a value (that functions as a ***'standard-deviation multiplier'*) marking where 95% of data points would be contained if our data is a normal distribution.

**To get the exact number**, we take the `norm.ppf()`

output and multiply it by our standard deviation for the distribution in question.

**A Two-Tailed Test**

If we need to calculate a 'Two-tail test' (i.e. We're concerned with values both greater *and* less than our mean) then we need to split the significance (i.e. our alpha value) *because we're still using a calculation method for one-tail*. The split in half symbolizes the significance level being appropriated to both tails. A 95% significance level has a 5% alpha; splitting the 5% alpha across both tails returns 2.5%. Taking 2.5% from 100% returns 97.5% as an input for the significance level.

Therefore, if we were concerned with values on both sides of our mean, our code would input .975 to represent a 95% significance level across two-tails:

```
norm.ppf(0.975, loc=172.7815, scale=4.1532)
```

**Margin of Error**

Margin of error is a significance level used when estimating a population parameter with a sample statistic. We want to generate our 95% confidence interval **using the two-tailed input** to `norm.ppf()`

since we're concerned with values both greater and less than our mean:

```
ppf = norm.ppf(0.975, loc=172.7815, scale=4.1532)
```

Next, we'd take the ppf and multiply it by our standard deviation to return the interval value:

```
interval_value = std * ppf
```

Finally, we'd mark the confidence intervals by adding & subtracting the interval value from the mean:

```
lower_95 = mean - interval_value
upper_95 = mean + interval_value
```

Plot with a vertical line:

```
_ = plt.axvline(lower_95, color='r', linestyle=':')
_ = plt.axvline(upper_95, color='r', linestyle=':')
```

`norm.isf()`

is more intuitive.