According to the reference docs, the arguments to `t.ppf`

are `q`

, `df`

, `loc`

, and `scale`

. The `df`

argument is degrees of freedom, which is usually the sample size minus 1 for a single population sampling problem. Since `ppf`

calculates the inverse cumulative distribution function, by definition a result of `x`

for a given `q`

-value and `df`

means `P{T <= x} = q`

, i.e, there is probability `q`

of getting outcomes less than or equal to `x`

from a `T`

distribution with the given `loc`

and `scale`

. The `loc`

(mean) and `scale`

(standard deviation) arguments are optional, and default to 0 and 1, respectively.

To get a 95% margin of error, you want 5% of the probability to be in the tails of the distribution. This is usually done symmetrically so that 2.5% is in each tail, so you would use `q`

values of 0.025 and 0.975 for the lower and upper cutoff points respectively. For your particular problem, the code would look something like:

```
from scipy.stats import t
n = 851
mean = 100
std_dev = 0.39
lower_cutoff = t.ppf(0.025, n - 1, loc = mean, scale = std_dev) # => 99.23452406698323
upper_cutoff = t.ppf(0.975, n - 1, loc = mean, scale = std_dev) # => 100.76547593301677
```