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辅导STAT3006程序、R/Python编程辅导

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辅导STAT3006程序、R/Python编程辅导
STAT3006 Assignment 3—Classification
Due Date: 15th October 2021
Weighting: 30%
Instructions
 The assignment consists of three (3) problems, each problem is worth 10 marks, and
each mark is equally weighted.
 The mathematical elements of the assignment can be completed by hand, in LaTeX (prefer-
ably), or in Word (or other typesetting software). The mathematical derivations and ma-
nipulations should be accompanied by clear explanations in English regarding necessary
information required to interpret the mathematical exposition.
 Computation problems can be answered using your programming language of choice, al-
though R is generally recommended, or Python if you are uncomfortable with R. As with
the mathematical exposition, you may choose to typeset your answers to the problems in
whatever authoring or word processing software that you wish. You should also maintain a
copy of any codes that you have produced.
 Computer generated plots and hand drawn graphs should be included together with the text
where problems are answered.
 The assignment will require four (4) files containing data, that you can can download from the
Assignment 3 section on Blackboard. These files are: p2_1ts.csv, p2_1cl.csv, p2_2ts.csv,
p3_1x.csv, p3_1y.csv, and data_bank_authentification.txt.
 Submission files should include the following (which ever applies to you):
– Scans of handwritten mathematical exposition.
– Typeset mathematical exposition, outputted as a pdf file.
– Program code/scripts that you wish to submit, outputted as a txt file.
1
 All submission files should be labeled with your name and student number and
archived together in a zip file and submitted at the TurnItIn link on Blackboard.
We suggest naming using the convention:
FirstName_LastName_STAT3006A3_[Problem_XX/Problem_XX_Part_YY].[FileExtension].
 As per my.uq.edu.au/information-and-services/manage-my-program/student-in
tegrityand-conduct/academic-integrity-and-student-conduct, what you submit
should be your own work. Even where working from sources, you should endeavour to write
in your own words. You should use consistent notation throughout your assignment and
define whatever is required.
Problem 1 [10 Marks]
Let X ∈ X = [0, 1] and Y ∈ {0, 1}. Further, suppose that
piy = P (Y = y) = 1/2
for both y ∈ {0, 1}, and that the conditional distributions of [X|Y = y] are characterized by the
probability density functions (PDFs):
f (x|Y = 0) = 2? 2x
and
f (x|Y = 1) = 2x.
Part a [2 Marks]
Consider the Bayes’ classifier for Y ∈ {0, 1} is
r (x) =1 if τ1 (x) > 1/2,0 otherwise,
where
τ1 (x) = P (Y = 1|X = x) .
Derive the explicit form of τ1 (x) in the current scenario and plot τ1 (x) as a function
of x.
2
Part b [2 Marks]
Define the classification loss function for a generic classifier r : X→ {0, 1} as
` (x, y, r (x)) = Jr (x) 6= yK ,
where ` : X× {0, 1} × {0, 1}, and consider the associated risk
L (r) = E (Jr (X) 6= Y K) .
It is known that the Bayes’ classifier is optimal in that it minimizes the classification risk, that is
L (r?) ≤ L (r) .
In the binary classification case,
L (r) = E (min {τ1 (X) , 1? τ1 (X)}) = 12 1
E (|2τ1 (X) 1|) .
Calculate L (r) for the current scenario.
Part c [2 Marks]
Assume now that pi1 ∈ [0, 1] is now unknown. Derive an expression for L (r?) that depends
on pi1.
Part d [2 Marks]
Assume again that pi1 ∈ [0, 1] is unknown. 
Then, assuming that pi0 = pi1 = 1/2, 
Consider now that pi1 ∈ [0, 1] is unknown, as are f (x|Y = 0) and f (x|Y = 1). That is, we only
know that f (·|Y = y) : X → R is a density function on X = [0, 1], for each y ∈ {0, 1}, in sense
3
Using the expressions from Part d, deduce the minimum and maximum values of L (r?)
and provide conditions on pi1, f (·|Y = 0) and f (·|Y = 1) that yield these values.
Problem 2 [10 Marks]
Suppose that we observe an independent and identically distributed sample of n = 300 random
pairs (Xi, Yi), for i ∈ [n], where Xi = (Xi1, . . . , Xid) is a mean-zero time series of length d = 100
and Yi ∈ {1, 2, 3} is a class label. Here, Xit is the observation of time series i ∈ [n] at time t ∈ [d]
and we may say that Xi ∈ X = Rd.
We assume that the label Yi, for i ∈ [n], is such that each class occurs in the general population
with unknown probability
piy = P (Yi = y) ,
for each y ∈ {1, 2, 3}, where ∑3y=1 piy = 1. Further, we know that Xit is first-order autoregressive,
in the sense that the distribution of [Xi|Y = y] can be characterized by the fact the conditional
probability densities
f (xir|Xi1 = xi1, Xi2 = xi2, . . . , Xi,r?1 = xi,r?1, Yi = y) = φ
(
xir; βyxi,r?1, σ2y
)
,
where xi = (xi1, . . . , xid) is a realization of Xi, and for each y ∈ {1, 2, 3}, σ2y ∈ (0,∞) and
βy ∈ [?1, 1]. 
is the univariate normal probability density function with mean μ ∈ R and variance σ2 ∈ (0,∞).
Part a [2 Marks]
Let (X, Y ) arise from the same population distribution as (X1, Y1). Using the information above,
derive expressions for the a posteriori probabilities
τy (x;θ) = P (Y = y|X = x) ,
for each y ∈ {1, 2, 3}, as functions of the parameter vector
 
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