Here is a post that I did in the Udacity forums that shows how to get a t-statistic appropriate for various sample sizes.

This should give you a t-statistic value similar to the values shown in the table at the bottom of this Wikipedia article.

Just in case anything happens to the first link, here is the code:

```
# -*- coding: utf-8 -*-
from __future__ import division
import math
from scipy.stats import t
def mean(lst):
# μ = 1/N Σ(xi)
return sum(lst) / float(len(lst))
def variance(lst):
"""
Uses standard variance formula (sum of each (data point - mean) squared)
all divided by number of data points
"""
# σ² = 1/N Σ((xi-μ)²)
mu = mean(lst)
return 1.0/len(lst) * sum([(i-mu)**2 for i in lst])
def get_tstat(probability, degrees_of_freedom, tails=2):
"""get the t-statistic required for confidence intetval calculations"""
if tails not in [1,2]:
sys.exit('invalid tails parameter (1 or 2 valid)')
inv_p = 1 - ((1 - probability) / tails)
return t.ppf(inv_p, degrees_of_freedom)
def conf_int(lst=None, p=0, n=0, perc_conf=95, tails=2):
"""
Confidence interval - supply a list OR a probability (p) and sample
size (n) e.g. if you want to know the confidence interval for 1000
coin tosses (0.5 p i.e. a fair coin) then call with (None, 0.5, 1000).
If a list id provided then the relevant stats are calculated on the
list from within the function so no p or n value is required.
The result gives a figure that you can be confident to conf (e.g
95% certain for 0.95) that the result will always be within this
amount +/- from the mean.
e.g. 1000 coin tosses returns ~0.03 on a fair coin (with 0.95 conf)
which means that you can be 95% confident of a getting within 3%
of the expected no of heads if you did this experiement.
"""
if lst:
n, v = len(lst), variance(lst)
t = get_tstat(perc_conf/100, n-1)
return math.sqrt(v/n) * t
else:
if not 0 < p < 1:
sys.exit('p parameter must be >0 and <1 if lst not given')
if n == 0:
sys.exit('n parameter must be >0 if lst not given')
t = get_tstat(perc_conf/100, n-1)
return t*(math.sqrt(p*(1-p)) / math.sqrt(n))
################################################################################
# Example: 1000 coin tosses on a fair coin. What is the range that I can be 95%
# confident the result will fall within.
################################################################################
# get confidence interval
sample_size, probability, perc_conf_req = 1000, 0.5, 95
c_int = conf_int(n=sample_size, p=probability, perc_conf=perc_conf_req)
# show results
exp_heads = probability * sample_size
x = round(sample_size * c_int, 0)
print 'I can be '+str(perc_conf_req)+'% confident that the result of '+ \
str(sample_size)+' coin flips will be within +/- '+ \
str(round(c_int*100,2))+'% of '+str(int(exp_heads)) + \
' i.e. between '+str(int(exp_heads-x))+' and '+str(int(exp_heads+x))+ \
' heads (assuming a probability of '+str(probability)+' for each flip).'
```