chapter two random variables and probability distributions 1
TRANSCRIPT
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Chapter twoChapter twoRandom variables and probability distributions
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1. COMBINATIONS 1. COMBINATIONS =The number of combinations of n distinct objects taken r at a time (r objects in each combination) = The number of different selections of r objects from n distinct objects. = The number of different ways to select r objects from n distinct objects. = The number of different ways to divide a set of n distinct objects into 2 subsets; one subset contains r objects and the other subset contains the rest.
2
r
n
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)!(!
!
rnr
n
r
n
3
12...)2()1(! nnnn
1!0
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Q1. Compute:
(a )
(b )
4
2
6
4
6
15
15
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Q2. Show that
5
xn
n
x
n
SHR ..
xn
n
))!(()!(
!
xnnxn
n
x
nSHL ..
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Q3. Compute:
)a(
)b(
)c(
6
0
n1
1
n n
1
n1
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Q4. A man wants to paint his house in 3 colors. If he can choose 3 colors out of 6 colors, how many different color settings can he make?
20
A.216.B.20.C.18.D.120.
7
3
6
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Q5. The number of ways in which we can select two students among a group of 5 students is
10
A.120B.10C.60D.20E.110
8
2
5
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Q6. The number of ways in which we can select a president and a secretary among a group of 5 students is
20A.120B.10C.60D.20
9
52P
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22 . .Probability, Conditional Probability, Conditional probability, and probability, and IndependenceIndependence . .
10
Q1. Let A, B, and C be three events such that: P(A)=0.5, P(B)=0.4, P(C∩Ac)=0.6, P(C∩A)=0.2, and P(A B)=0.9. Then∪
(a)P(C) =A. 0.1 B. 0.6 C. 0.8 D. 0.2 E. 0.5
(b) P(B∩A) =A. 0.0 B. 0.9 C. 0.1D. 1.0 E. 0.3
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(c) P (C|A) =A. 0.4 B. 0.8 C. 0.1 D. 1.0 E. 0.7
(d)
A. 0.3B. 0.1C. 0.2 D. 1.1 E. 0.8
)( cc ABP
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Q2. Consider the experiment of flipping a balanced coin three times independently.
S = {H, T} ᵡ {H, T} ᵡ {H, T} . = {HHH, HHT, HTH, THH, HTT, THT, TTH, TTT}.
(a)The number of points in the sample space isA. 2 B. 6 C. 8 D. 3E. 9
(b) The probability of getting exactly two heads is A. 0.125 B. 0.375 C. 0.667 D. 0.333E. 0.451
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(c) The events ‘exactly two heads’ and ‘exactly three heads’ areA. Independent B. disjoint C. equally likelyD. identicalE. None
(d) The events ‘the first coin is head’ and ‘the second and the third coins are tails’ are
A. Independent B. disjoint C. equally likely D. identical E. None
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Q3. Suppose that a fair die is thrown twice independently, then
S = {(1,1), (1,2), (1,3), (1,4), (1,5), (1,6) ……………………………….., (6,6)}
1. the probability that the sum of numbers of the two dice is less than or equal to 4 is
A. 0.1667B. 0.6667C. 0.8333 D. 0.1389
2. the probability that at least one of the die shows 4 is;A. 0.6667B. 0.3056C. 0.8333D. 0.1389
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3. the probability that one die shows one and the sum of the two dice is four is;
A. 0.0556B. 0.6667 C. 0.3056 D. 0.1389
4. the event A={the sum of two dice is 4} and the event B={exactly one die shows two} are,
A. IndependentB. Dependent C. Joint D. None of these.
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Q4. Assume that P(A)= 0.3, P(B)= 0.4, P(A∩B∩C)=0.03, and , then
1.the events A and B areA. IndependentB. Dependent C. Disjoint D. None of these.
2. is equal to,A. 0.65 B. 0.25 C. 0. 35D. 0.14
Q5. If the probability that it will rain tomorrow is 0.23, then the probability that it will not rain tomorrow is:
A. −0.23 B. 0.77 C. −0.77 D. 0.23
88.0)( BAP
)/( BACP
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Q6. The probability that a factory will open a branch in Riyadh is 0.7, the probability that it will open a branch in Jeddah is 0.4, and the probability that it will open a branch in either Riyadh or Jeddah or both is 0.8. Then, the probability that it will open a branch:
1) in both cities is:A. 0.1B. 0.9 C. 0.3 D. 0.8
2) in neither city is:A. 0.4 B. 0.7 C. 0.3 D. 0.2
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Q7. The probability that a lab specimen is contaminated is 0.10. Three independent specimen are checked.
1)the probability that none is contaminated is:
A. 0.0475B. 0.001 C. 0.729 D. 0. 3
2) the probability that exactly one sample is contaminated is:
A. 0.243B. 0.081C. 0.757D. 0. 3
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Q8. 200 adults are classified according to sex and their level of education in the following table:
If a person is selected at random from this group, then:
1) the probability that he is a male is:A. 0.3182 B. 0.44 C. 0.28 D. 78
sexEducation
Male )M(Female )F(
Elementary )E(
2850
Secondary )S(
3845
College )C(2217
19
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2) The probability that the person is male given that the person has a secondary education is:
A. 0.4318 B. 0.4578 C. 0.19 D. 0.44
3) The probability that the person does not have a college degree given that the person is a female is:
A. 0.8482 B. 0.1518 C. 0.475 D. 0.085
4) Are the events M and E independent? Why? P(M)=0.44 ≠P(M|E)=0.359
⇒ dependent
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Q9. 1000 individuals are classified below by sex and smoking habit.
sex
Male )M(Female )F(
SMOKINGHABIT
Daily )D(30050
Occasionally )O(
20050
Not at all )N(100300
A person is selected randomly from this group.1.Find the probability that the person is female.P(F)=0.4
2. Find the probability that the person is female and smokes daily. P(F∩D)=0.05
3. Find the probability that the person is female, given that the person smokes daily. P(F|D)=0.1429
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4. Are the events F and D independent? Why? P(F)=0.4 ≠ P(F|D)=0.1429 ⇒ dependent
Q10. Two engines operate independently, if the probability that an engine will start is 0.4, and the probability that the other engine will start is 0.6 then the probability that both will start is:
A. 1 B. 0.24 C. 0.2D. 0.5
Q11. If P(B)= 0.3 and P(A/B)= 0.4, then P(A∩B) equals to;
A. 0.67 B. 0.12C. 0.75 D. 0.3
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4 2
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Q16. If P(A1)=0.4, P(A1∩A2)=0.2, and P(A3|A1∩A2)=0.75, then(1) P(A2|A1) equals to
A. 0.00 B. 0.20 C. 0.08 D. 0.50
(2) P(A1∩A2∩A3) equals toA. 0.06 B. 0.35C. 0.15 D. 0.08
Q17. If P(A)=0.9, P(B)=0.6, and P(A∩B)=0.5, then:(1) equals to
A. 0.4 B. 0.1 C. 0.5 D. 0.3
)( cBAP
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(2) equals toA. 0.2 B. 0.6C. 0.0D. 0.5
(3) P(B|A) equals toA. 0.5556B. 0.8333C. 0.6000D. 0.0
(4) The events A and B areA. IndependentB. DisjointC. jointD. none
(5) The events A and B areA. DisjointB. DependentC. independent D. none
)( cc BAP
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Q18. Suppose that the experiment is to randomly select with replacement 2 children and register their gender (B=boy, G=girl) from a family having 2 boys and 6 girls.
P(B)=2/8=1/4 and P(G)= 6/8=3/4(1) The number of outcomes (elements of the sample space) of this experiment equals to
A. 4 B. 6 C. 5 D. 125
(2) The event that represents registering at most one boy isA. {GG, GB, BG} B. {GB, BG}C. {GB}ᶜD. {GB, BG, BB}
(3) The probability of registering no girls equals toA. 0.2500 B. 0.0625 C. 0.4219 D. 0.1780
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(4) The probability of registering exactly one boy equals toA. 0.1406B. 0.3750 C. 0.0141 D. 0.0423
(5) The probability of registering at most one boy equals toA. 0.0156B. 0.5000C. 0.4219D. 0.9375
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Random Variables, Random Variables, distributions, Expectations distributions, Expectations and Chebyshev’s Theoremand Chebyshev’s Theorem..
4.1. DISCRETE DISTRIBUTIONS:
Q1. Consider the experiment of flipping a balanced coin three times independently.
Let X= Number of heads – Number of tails.
X = # H - # T.
)a(List the elements of the sample space S.
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S = {TTT, TTH, TTH, THT, THH, HTT, HTH, HHT, HHH}
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(b) Assign a value x of X to each sample point.
Sample element
#of H #of TX
TTT030-3-=3
TTH121-2-=1
THT121-2-=1
THH212-1=1
HTT121-2-=1
HTH212-1=1
HHT212-1=1
HHH303-1=3
X = -3, -1, 1, 3
X-3-113
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(c) Find the probability distribution function of X.
f(-3)= P(X=-3) =P({TTT}) = 1/8. f(-1) = P(X = -1) = P({TTH, THT, HTT}) = 3/8. f(1) = P(X = 1) = P({THH, HTH, HHT }) = 3/8. f(3) = P(X = 3) = P({HHH}) = 1/8.
X-3-113
f)x(1/83/83/81/8
18/18/38/38/1
(d) Find P( X ≤ 1 ).P(X ≤ 1) = 7/8
(e) Find P( X < 1 ).P( X < 1) = 4/8=1/2
(f) Find μ = E(X).
⇒ E(X) = 0
X-3-113
x f)x(-3/8-3/83/83/8
)(08/38/38/38/3 XE
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(g ) = Var (X).Find 2
22 )()()( XEXEXVar
remember
2X 9 1 1 9
)(2 xfx 8/9 8/3 8/3 8/9
38/248/98/38/38/9 )( 2XE
Var (X) = 3 - = 320
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Q2. It is known that 20% of the people in a certain human population are female. The experiment is to select a committee consisting of two individuals at random. Let X be a random variable giving the number of females in the committee.
population have 20% females (F) ⇒P(F) = 20/100 = 0.2
and P(M) = 1 – 0.2 = 0.8
1 .List the elements of the sample space S.
S = {FF, FM, MF, MM}
2. Assign a value x of X to each sample point.
x 0 1 2
3. Find the probability distribution function of X.
x
)(xf0
64.0
1
32.0
2
04.0
1
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4. Find the probability that there will be at least one female in the committee.
at least ( ≥ )
P( X ≥ 1) = 0.36 .
5. Find the probability that there will be at most one female in the committee.
at most ( ≤ )
P( X ≤ 1) = 0.96 .
6 .Find μ = E(X).
x
xxfXE )()(
remember
E(X) = 0.4
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7. = Var (X).Find 2
22 )()()( XEXEXVar
remember
x
xfxXE )()( 22
andVar(X) = 0.32
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Q3. A box contains 100 cards; 40 of which are labeled with the number 5 and the other cards are labeled with the number 10. Two cards were selected randomly with replacement and the number appeared on each card was observed. Let X be a random variable giving the total sum of the two numbers.
10
5
40
60
100 card
2 cards
X = #of first card
+ #of second card
(i )List the elements of the sample space S.
S = {( 5, 5), (5, 10), (10, 5), (10, 10)}.
with replacement
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(ii) To each element of S assign a value x of X.
x 10 15 20
(iii) Find the probability mass function (probability distribution function) of X.
x
)(xf10
16.0
15
48.0
20
36.0
1
(iv )Find P)X=0(.
P(X=0) = 0
(v) Find P(X>10).
P(X>10) = 0.84
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(vi) Find μ=E(X).
x
xxfXE )()(
remember
E(X) = 16
(vii) = Var (X).Find 2
22 )()()( XEXEXVar
remember
x
xfxXE )()( 22
and
Var(X) = 12
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Q4. Let X be a random variable with the following probability distribution:
X-369
f)x(0.10.50.4
1) Find the mean (expected value) of X, μ=E(X).
x
xxfXE )()(
rememberE(X) = 6.3
2 )Find ).( 2XE
x
xfxXE )()( 22
remember
)( 2XE 51.3
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3 )Find the variance of X, 2)( XXVar
22 )()()( XEXEXVar
rememberVar(X) = 11.61
4) Find the mean of 2X+1, .)12( 12 XXE
)( baXE
remember
)(XaE b
)12( XE 13.6
5 )Find the variance of 2X+1, .)12( 212 XXVar
)( baXVarremember
2a )(XVar )12( XVar 46.44
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Q5. Which of the following is a probability distribution function:
(A ) ;10
1)(
x
xf 4,3,2,1,0x (B ) ;5
1)(
x
xf 4,3,2,1,0x
(C ) ;5
1)( xf 4,3,2,1,0x (D ) ;
6
5)(
2xxf
3,2,1,0x
remember
)(xf is p.d.fif
.,1)(0 xxf 1. 2. 1)( x
xf
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Q6. Let the random variable X have a discrete uniform with parameter k=3 and with values 0,1, and 2. The probability distribution function is:
;31)()( xXPxf .2,1,0x
(1) The mean of X is
(A) 1.0 (B) 2.0 (C) 1.5 (D) 0.0
(2) The variance of X is
(A) 0.0 (B) 1.0 (C) 0.67 (D) 1.33
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Q7. Let X be a discrete random variable with the probability distribution function:
kxxf )( for .3,2,1x
(i )Find the value of k.remember
1)( x
xf61k
(ii) Find the cumulative distribution function (CDF), F(x).
remember
xX
xfxXPxF )()()(
.
31
326/3
216/1
10
)(
x
x
x
x
xF
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(iii) Using the CDF, F(x), find P (0.5 < X ≤ 2.5).
remember
)( bxaP )()( aFbF
)5.25.0( xP 1/2
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Q8. Let X be a random variable with cumulative distribution function (CDF) given by:
.
21
216.0
1025.0
00
)(
x
x
x
x
xF
(a) Find the probability distribution function of X, f(x).
x
)(xf0
25.0
1
35.0
2
40.0
1
remember
)1()()( xFxFxf
(b) Find P( 1≤X<2). (using both f(x) and F(x)).
remember
)( bxaP )1()1( aFbF )5.25.0( xP 0.3
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(c) Find P( X>2). (using both f(x) and F(x)). remember
)(1)( xFxXP )2(XP 0
Q9. Consider the random variable X with the following probability distribution function:
X0123
f)x(0.4c0.30.1
The value of c isremember
1)( x
xf
(A) 0.125 (B) 0.2 (C) 0.1 (D) 0.125 (E) -0.2
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Q10. Consider the random variable X with the following probability distribution function:
X-1012
f)x(0.20.30.2c
Find the following:
(a )The value of c.
c = 0.3
remember
1)( x
xf
(b) P( 0 < X ≤ 2 ). = 0.5
(c) μ = E(X).
x
xxfXE )()(
remember
E(X) = 0.6
(d) ).( 2XE
x
xfxXE )()( 22
remember
)( 2XE 1.6
(e) 2)( XXVar
22 )()()( XEXEXVar
rememberVar(X) = 1.24
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Q11. Find the value of k that makes the function
xxkxf
3
32)( for .2,1,0x
serve as a probability distribution function of the discrete random variable X.
remember
1)( x
xfkk = 0.1
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Q12. The cumulative distribution function (CDF) of a discrete random variable, X, is given below:
41
4316/15
3216/11
2116/5
1016/1
00
)(
x
x
x
x
x
x
xF
(a) The P(X = 2) is equal to:
(A) 3/8 (B) 11/16 (C) 10/16 (D) 5/16
remember
)1()()( xFxFxf
(b) The P(2 ≤ X < 4) is equal to:remember
)( bxaP )1()1( aFbF
(A) 20/16 (B) 11/16 (C) 10/16 (D) 5/16
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Q13. If a random variable X has a mean of 10 and a variance of 4, then, the random variable Y = 2X – 2 ,
(a) has a mean of:
(A) 10 (B) 18 (C) 20 (D) 22
)( baXE
remember
)(XaE b
(b) and a standard deviation of: remember2
Y
)(YE
and222XbaX a
(A) 6 (B) 2 (C) 4 (D) 16
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50
Q14. Let X be the number of typing errors per page committed by a particular typist. The probability distribution function of X is given by:
X01234
f)x(3k3k2kkk
(1) Find the numerical value of k.remember
1)( x
xfK=1/10=0.1
(2) Find the average (mean) number of errors for this typist.
Average= mean=μ
x
xxfXE )()(and
μ = E(X) = 1.4
(3) Find the variance of the number of errors for this typist.
22 )()()( XEXEXVar
remember
V(X) = 1.64
6.3)( 2 XE
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(4) Find the cumulative distribution function (CDF) of X.
41
439.0
328.0
216.0
103.0
00
)(
x
x
x
x
x
x
xF
(5) Find the probability that this typist will commit at least 2 errors per page.
P(X ≥ 2) = 0.4
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52
Q15. Suppose that the discrete random variable X has the following probability function: f(−1)=0.05, f(0)=0.25, f(1)=0.25, f(2)=0.45, then:
(A) 0.30 (B) 0.05 (C) 0.55 (D) 0.50
(1) P(X < 1) equals to
(2) P(X ≤ 1) equals to
(A) 0.05 (B) 0.55 (C) 0.30 (D) 0.45
(3) The mean μ = E(X) equals to
(A) 1.1 (B) 0.0 (C) 2.10 (D) 0.75
(4) )( 2XE equals to
(A) 2.00 (B) 2.10 (C) 1.50 (D) 0.75
(5) The variance )(2 XVar equals to
(A) 1.00 (B) 3.31 (C) 0.89 (D) 2.10
(6) If F(x) is the cumulative distribution function (CDF) of X, then F(1) equals to
(A) 0.50 (B) 0.25 (C) 0.45 (D) 0.55
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Continuous DistributionsContinuous Distributions::
53
Q1. If the continuous random variable X has mean μ=16 and variance , then P(X=16) is
elsewhere
xxkxf
0
10)(
52
cx
dxx )2/3(
2/3
Q2. Consider the probability density function:
[Hint: ]
0)( kXPIf X continuous random variable then
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1 )The value of k is:
)A) 1 )B) 0.5 )C) 1.5 )D) 0.667
)A) 0.4647
)B) 0.3004
)C) 0.1643)D) 0.4500
)A )0.6 )B)1.5
)C )1 ) D )0.667
1)(
dxxf
b
a
dxxfbXaP )()(
dxxxfXE )()(
2) The probability P(0.3 < X ≤ 0.6) is,
3) The expected value of X, E(X)is,
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55
Q3. Let X be a continuous random variable with the probability density function f(x)=k(x+1) for 0<x<2.
)i )Find the value of k.
0.25
1)(
dxxf
)ii) Find P)0 < X ≤ 1). b
a
dxxfbXaP )()(
0.375
)iii )Find the cumulative distribution function
)CDF) of X, F(x) .
x
dxxfxXPxF )()()(
21
20)2(
10
100
)(2
x
xxx
x
xF
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)iv) Using F)x), find P)0 < X ≤ 1).
)()()( aFbFbXaP =0.375
Q4. Let X be a continuous random variable with the probability density function f(x)= for −1< x < 1.
2/3 2x
1. P)0 < X < 1) = b
a
dxxfbXaP )()(
0.5
2. E)X) =
dxxxfXE )()(
0.0
3. Var)X) = 22 )()()( XEXEXVar 0.6
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4. E)2X+3)=bXaEbaXE )()(
3
5. Var)2X+3)= )()( 2 XVarabaXVar
2.4
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58
Q5. Suppose that the random variable X has the probability density function:
elsewhere
xkxxf
0
20)(
1 .Evaluate k.= 1/2
2. Find the cumulative distribution function )CDF) of X, F)x).
21
204
00
)(2
x
xx
x
xF
3. Find P)0 < X < 1).
= 1/4
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59
4. Find P)X = 1) and P)2 < X < 3).
P(X = 1)= 0 P(2 < X < 3)= 0
Q6. Let X be a random variable with the probability density function:
elsewhere
xxxxf
0
10)1(6)(
1 .Find μ = E)X(.
=1/2 2. Find σ2 = Var)X(.
=1/20
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3. Find E )4X+5(.
= 9
4. Find Var)4X+5(.
=4/5
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61
Q7. If the random variable X has a uniform distribution on the interval )0,10( with the probability density function given by:
,0
10010
1)(
eleswhere
xxf
1. Find P)X<6(.
x
dxxfxXP )()(
= 0.6
2. Find the mean of X.
dxxxfXE )()(
= 5
3. Find .)( 2XE
dxxfxXE )()( 22
= 33.33
4. Find the variance of X.
22 )()()( XEXEXVar
remember
= 8.33
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5. Find the cumulative distribution function )CDF( of X, F)x(.
x
dxxfxXPxF )()()(
101
10010
00
)(
x
xx
x
xF
6. Use the cumulative distribution function, F)x(, to find P)1<X≤5(.
b
a
dxxfbXaP )()(
= 0.4
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63
Q8. Suppose that the failure time )in months( of a specific type of electrical device is distributed with the probability density function:
,0
10050
1)(
eleswhere
xxxf
)a( the average failure time of such device is:
)A( 6.667 )B( 1.00 )C( 2.00 )D(5.00
)b( the variance of the failure time of such device is:
)A( 0 )B( 50 )C( 5.55 )D(10
)c( P)X > 5( =
)A( 0.25 )B( 0.55 )C( 0.65 )D(0.75
dxxxfXE )()(
22 )()()( XEXEXVar
x
dxxfxXP )()(
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64
Q9. If the cumulative distribution function of the random variable X having the form:
0)1(
00)()( xx
xx
xFxXP
Then)1( P)0 < X < 2( equals to )()()( aFbFbXaP
)A( 0.555 )B( 0.333 )C( 0.667 )D( none of these
)2( If P)X ≤ k( = 0.5 , then k equals to
)A( 5 )B( 0.5 )C(1 )D(1.5
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65
Q10. If the diameter of a certain electrical cable is a continuous random variable X ) in cm ( having the probability density function :
,0
10)1(20)(
3
otherwise
xxxxf
)1( P)X > 0.5( is:
)A( 0.8125
)B( 0.1875 )C( 0.9844 )D( 0.4445
)2( P)0.25 <X < 1.75( is:
)A( 0.8125
)B( 0.1875 )C( 0.9844 )D( 0.4445
(3) μ = E)X( is:
)A( 0.667 )B( 0.333 )C( 0.555 )D( None of these
)4( = Var)X( is: 2
)A( 0.3175
)B( 3.175 )C( 0.0317 )D( 2.3175
dxxxfXE )()(
22 )()()( XEXEXVar
x
dxxfxXP )()(
b
a
dxxfbXaP )()(
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)5( For this random variable, P)µ - 2 σ ≤ X≤ µ + 2 σ ( will have an exact value equals to:
)A( 0.3175
)B( 0.750 )C( 0.965 )D( 0.250
)6( For this random variable, P)µ - 2 σ ≤ X≤ µ + 2 σ ( will have a lower bound value according to chebyshev’s theory equals to:
2
11)(
KKXKP
)A( 0.3175
)B( 0.750 )C( 0.965 )D( 0.250
)7( If Y= 3X−1.5, then E)Y( is: bXaEbaXE )()(
)A( - 0.5 )B( – 0.3335
)C( 0.5 )D( None of these
(8 )If Y= 3X−1.5, then Var)Y( is:
)A( 2.8575
)B( 0.951 )C( 0.2853 )D( 6.9525
)()( 2 XVarabaXVar
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Chebyshev’s TheoremChebyshev’s Theorem::
67
Q1. According to Chebyshev’s theorem, for any random variable X with mean μ and variance σ2, a lower bound for P)µ - 2 σ ≤ X≤ µ + 2 σ ( is,
)A( 0.3175
)B( 0.750 )C( 0.965 )D( 0.250
Note: P)µ - 2 σ ≤ X≤ µ + 2 σ( = P)|X - µ| < 2σ(
2
11)|(|)(
KKXPKXKP
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68
Q2. Suppose that X is a random variable with mean μ=12, variance =9, and unknown probability distribution. Using Chebyshev’s theorem, P)3 < X < 21( is at least equal to,
2
2
11)(
KKXKP
)A( 8/9 )B( 3/4 )C( 1/4 )D( 1/16
Q3. Suppose that E)X(=5 and Var)X(=4. Using Chebyshev's Theorem,
)i( find an approximated value of P)1<X<9(.
2
11)(
KKXKP
≈ 0.25
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)ii( find some constants a and b )a<b( such that P)a<X<b( ≈ 15/16.
2
11)(
KKXKP
a = -3 b = 9
Q4. Suppose that the random variable X is distributed according to the probability density function given by:
,0
10010
1)(
eleswhere
xxf
Assuming μ=5 and σ = 2.89,
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1. Find the exact value of P)μ−1.5σ < X <μ+1.5σ(.
b
a
dxxfbXaP )()(
= 0.867
2. Using Chebyshev's Theorem, find an approximate value of P)μ−1.5σ < X <μ+1.5σ(.
2
11)(
KKXKP
≈ 0.556
3. Compare the values in )1( and )2(.
0.867 > 0.556
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Q5. Suppose that X and Y are two independent random variables with E)X(=30, Var)X(=4, E)Y(=10, and Var)Y(=2. Then:
bXaEbaXE )()()1( E)2X−3Y−10( equals to
)A( 40 )B( 20 )C( 30 )D( 90
)2( Var)2X−3Y−10( equals to )()( 2 XVarabaXVar
)A( 34 )B( 24 )C( 2.0 )D( 14
)3( Using Chebyshev's theorem, a lower bound of P)24<X<36( equals to
2
11)(
KKXKP
)A( 0.3333
)B( 0.6666 )C( 0.8888 )D( 0.1111
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SOME DISCRETE SOME DISCRETE PROBABILITY PROBABILITY DISTRIBUTIONSDISTRIBUTIONS
CHAPTER FOUR
72
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DISCRETE UNIFORM DISCRETE UNIFORM DISTRIBUTIONDISTRIBUTION::
73
Q1. Let the random variable X have a discrete uniform with parameter k=3 and with values 0,1, and 2. Then:
(b) The mean of X is
(A) 1.0 (B) 2.0 (C) 1.5 (D) 0.0
(c) The variance of X is
(A) 0/3=0.0 (B) 3/3=1.0 (C) 2/3=0.67 (D) 4/3=1.33
(E) None
(E) None
(a) P(X=1) is
(A) 1.0 (B) 1/3 (C) 0.3 (D) 0.1 (E) None
KxXP
1)( Kxxxx ,...,,, 21
K
XK
ii
1
K
XK
ii
1
2
2
)(
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5. BINOMIAL DISTRIBUTION:5. BINOMIAL DISTRIBUTION:
74
Q1. Suppose that 4 out of 12 buildings in a certain city violate the building code. A building engineer randomly inspects a sample of 3 new buildings in the city.
(a) Find the probability distribution function of the random variable X representing the number of buildings that violate the building code in the sample.
)(xfxx
x
3
3
2
3
133,2,1,0x
(b) Find the probability that:
(i) none of the buildings in the sample violating the building code.
f(0) = 0.296
(ii) one building in the sample violating the building code.
f(1) = 0.444
nx ,...,1,0, xnxqpx
npnxb
),,(
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75
(iii) at lease one building in the sample violating the building code.
P(X ≥ 1) = 0.704
(c) Find the expected number of buildings in the sample that violate the building code (E(X)).
E(X) = 1
(d) Find ).(2 XVar
Var(X) = 2/3Q2. A missile detection system has a probability of 0.90 of detecting a missile attack. If 4 detection systems are installed in the same area and operate independently, then
(a) The probability that at least two systems detect an attack is
(A) 0.9963 (B) 0.9477 (C) 0.0037 (D) 0.0523 (E) 0.5477
(b) The average (mean) number of systems detect an attack is
(A) 3.6 (B) 2.0 (C) 0.36 (D) 2.5 (E) 4.0
npXE )(
npqXVar )(
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76
Q3. Suppose that the probability that a person dies when he or she contracts a certain disease is 0.4. A sample of 10 persons who contracted this disease is randomly chosen.
(1) What is the expected number of persons who will die in this sample?
μ = 4
(2) What is the variance of the number of persons who will die in this sample?
4.22 (3) What is the probability that exactly 4 persons will die among this sample?
f(4) = 0.2149
(4) What is the probability that less than 3 persons will die among this sample?
less than 3 ( < 3 ) ⇒
P(X < 3) = 0.
(5) What is the probability that more than 8 persons will die among this sample?
more than 8 ( > 8 ) ⇒
P(X > 3) = 0.345
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77
Q4. Suppose that the percentage of females in a certain population is 50%. A sample of 3 people is selected randomly from this population.
(a) The probability that no females are selected is
(A) 0.000 (B) 0.500 (C) 0.375 (D) 0.125
(b) The probability that at most two females are selected is
(A) 0.000 (B) 0.500 (C) 0.875 (D) 0.125
(c) The expected number of females in the sample is
(A) 3.0 (B) 1.5 (C) 0.0 (D) 0.50
(d) The variance of the number of females in the sample is
(A) 3.75 (B) 2.75 (C) 1.75 (D) 0.75
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Q5. 20% of the trainees in a certain program fail to complete the program. If 5 trainees of this program are selected randomly,
(i) Find the probability distribution function of the random variable X, where:X = number of the trainees who fail to complete the program.
)(xf xx
x
58.02.05
5,...,1,0x
(ii) Find the probability that all trainees fail to complete the program.
f(5) = 0.00032
(iii) Find the probability that at least one trainee will fail to complete the program.
P(X ≥ 1) = 0.674
(iv) How many trainees are expected to fail completing the program?
μ = 1
(v) Find the variance of the number of trainees who fail completing the program.
8.02
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79
Q6. In a certain industrial factory, there are 7 workers working independently. The probability of accruing accidents for any worker on a given day is 0.2, and accidents are independent from worker to worker.
(a) The probability that at most two workers will have accidents during the day is
(A) 0.7865 (B) 0.4233 (C) 0.5767 (D) 0.6647
(b) The probability that at least three workers will have accidents during the day is:
(A) 0.7865 (B) 0.4233 (C) 0.5767 (D) 0.6647
(A) 1.4 (B) 0.2135 (C) 2.57 (D) 0.59
(c) The expected number workers who will have accidents during the day is
Q7. From a box containing 4 black balls and 2 green balls, 3 balls are drawn independently in succession, each ball being replaced in the box before the next draw is made. The probability of drawing 2 green balls and 1 black ball is:
(A) 6/27 (B) 2/27 (C) 12/27 (D) 4/27
4 2 3
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Q8. The probability that a lab specimen is contaminated is 0.10. Three independent samples are checked.
1) the probability that none is contaminated is:
(A) 0.0475 (B) 0.001 (C) 0.729 (D) 0.3
2) the probability that exactly one sample is contaminated is:
(A) 0.243 (B) 0.081 (C) 0.757 (D) 0.3
Q9. If X~Binomial(n,p), E(X)=1, and Var(X)=0.75, find P(X=1).
remember
E(X) = np and Var(X) = npq
P(X = 1) = 0.422
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Q11. A traffic control engineer reports that 75% of the cars passing through a checkpoint are from Riyadh city. If at this checkpoint, five cars are selected at random.
(1) The probability that none of them is from Riyadh city equals to:
(A) 0.00098 (B) 0.9990 (C) 0.2373 (D) 0.7627
(2) The probability that four of them are from Riyadh city equals to:
(A) 0.3955 (B) 0.6045 (C) 0 (D) 0.1249
(3) The probability that at least four of them are from Riyadh city equals to:
(A) 0.3627 (B) 0.6328 (C) 0.3955 (D) 0.2763
(4) The expected number of cars that are from Riyadh city equals to:
(A) 1 (B) 3.75 (C) 3 (D) 0