Algorithms Exercise 3

Imports



In [1]:

    
%matplotlib inline
from matplotlib import pyplot as plt
import numpy as np



In [2]:

    
from IPython.html.widgets import interact









    



:0: FutureWarning: IPython widgets are experimental and may change in the future.

Character counting and entropy

Write a function char_probs that takes a string and computes the probabilities of each character in the string:

First do a character count and store the result in a dictionary.
Then divide each character counts by the total number of character to compute the normalized probabilties.
Return the dictionary of characters (keys) and probabilities (values).



In [19]:

    
def char_probs(s):
    """Find the probabilities of the unique characters in the string s.
    
    Parameters
    ----------
    s : str
        A string of characters.
    
    Returns
    -------
    probs : dict
        A dictionary whose keys are the unique characters in s and whose values
        are the probabilities of those characters.
    """
    count = []
    char = []
    for i in range(len(s)):
        if not s[i] in char:
            char.append(s[i])
            count.append(1)
        elif s[i] in char:
            for j in range(len(char)):
                if char[j]==s[i]:
                    count[j]+=1
    prob = []
    for l in range(len(count)):
        prob.append(count[l]/len(s))
    cc = []
    for k in range(len(char)):
        cc.append((char[k],prob[k]))
    ccd = dict(cc)
    return ccd



In [ ]:

    
def f(n):



In [47]:

    
d=char_probs('abcd')
list(map(lambda d[x]: x in list(iter(d)), d))









    



  File "<ipython-input-47-09965e8c2c84>", line 2
    list(map(lambda d[x]: x in list(iter(d)), d))
                     ^
SyntaxError: invalid syntax



In [21]:

    
test1 = char_probs('aaaa')
assert np.allclose(test1['a'], 1.0)
test2 = char_probs('aabb')
assert np.allclose(test2['a'], 0.5)
assert np.allclose(test2['b'], 0.5)
test3 = char_probs('abcd')
assert np.allclose(test3['a'], 0.25)
assert np.allclose(test3['b'], 0.25)
assert np.allclose(test3['c'], 0.25)
assert np.allclose(test3['d'], 0.25)

The entropy is a quantiative measure of the disorder of a probability distribution. It is used extensively in Physics, Statistics, Machine Learning, Computer Science and Information Science. Given a set of probabilities $P_i$, the entropy is defined as:

$$H = - \Sigma_i P_i \log_2(P_i)$$

In this expression $\log_2$ is the base 2 log (np.log2), which is commonly used in information science. In Physics the natural log is often used in the definition of entropy.

Write a funtion entropy that computes the entropy of a probability distribution. The probability distribution will be passed as a Python dict: the values in the dict will be the probabilities.

To compute the entropy, you should:

First convert the values (probabilities) of the dict to a Numpy array of probabilities.
Then use other Numpy functions (np.log2, etc.) to compute the entropy.
Don't use any for or while loops in your code.



In [ ]:

    
def entropy(d):
    """Compute the entropy of a dict d whose values are probabilities."""
    P = np.array()



In [ ]:

    
assert np.allclose(entropy({'a': 0.5, 'b': 0.5}), 1.0)
assert np.allclose(entropy({'a': 1.0}), 0.0)

Use IPython's interact function to create a user interface that allows you to type a string into a text box and see the entropy of the character probabilities of the string.



In [ ]:

    
# YOUR CODE HERE
raise NotImplementedError()



In [ ]:

    
assert True # use this for grading the pi digits histogram