I couldn't understand how to properly use t.ppf, could someone please explain it to me?

I have to use this information

  • scipy.stats.t
  • scipy.stats
  • a mean of 100
  • a standard deviation of 0.39
  • N = 851 (851 samples)

When I'm asked to calculate the (95%) margin of error using t.ppf() will the code look like below?

cutoff1 = t.ppf(0.05,100,0.36,850) 

Can somebody help me, please?

2 Answers 2


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
  • 95%CI is mentioned to be mean+/-1.96*SE where SE = SD/sqrt(N) ; See here: amsi.org.au/ESA_Senior_Years/SeniorTopic4/4h/… ; By this formula, one get these values: 99.973796 and 100.02620329 ; Why are these values so much different from values obtained in this answer?
    – rnso
    Jan 13, 2022 at 13:35
  • Actually values obtained in the answer (99.234 and 100.765) are obtained with formula of mean+/-1.96*SE if SE=SD/1 i.e. when N=1 (so that sqrt(1) is 1)
    – rnso
    Jan 13, 2022 at 14:20
  • 1
    @rnso The question explicitly asked about t.ppf rather than t.interval, so I assumed they were asking for percentiles under the assumption of normality with known mean but unknown variance, and not about a CI. The difference is a factor of sqrt(n) for the CI half-width. t.interval(0.05, n - 1, loc = mean, scale = std_dev) yields a CI of (99.97553713440418, 100.02446286559582), in line with your comment. Note that using 1.96 assumes the t distribution has asymptotically converged to normal -- not a bad assumption for n = 851 -- but only gives three significant digits.
    – pjs
    Jan 13, 2022 at 14:59
  • Very well explained. Thanks.
    – rnso
    Jan 13, 2022 at 16:43
  • The df argument is degrees of freedom, which is usually the sample size minus 1 for a single population sampling problem. Why minus 1?
    – NoName
    Jul 19, 2022 at 16:47

I'm almost certain you have to use standard error instead, which is std/sqrt(n)

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