The question discusses a binomial problem. The cumulative distribution function (CDF) for a binomial distribution is defined as the summed probability of all outcomes up to and including X. To compute the CDF, add up the probabilities of all outcomes up to X.
Explanation:The problem described in the question is a binomial problem. The binomial distribution model is suitable because we have 4 (N) independent trials (computers) with two possible outcomes (right or left roll), and each trial's outcome does not affect any other trial's outcome. The probability that a computer will ask for a roll to the left when a roll to the right is appropriate is 0.0005 (p). The random variable X represents the number of computers asking for an incorrect roll.
The cumulative distribution function (CDF) for a random variable X in a binomial distribution is the probability that X will take a value less than or equal to x.
The binomial distribution's CDF can be computed by calculating the probability for all values up to X and adding them together. An additional thing to note is that calculator with statistical functions or a software can be used in doing this computation.
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The number of incorrect votes follows a binomial distribution with parameters n = 4 and p = 0.0005. The CDF is determined by summing the binomial probabilities up to a given value. The CDF values for X = 0 through X = 4 are calculated step-by-step.
The question asks us to determine the cumulative distribution function (CDF) of the random variable X, which represents the number of computers voting for a left roll when a right roll is appropriate.
This scenario follows a binomial distribution, where each computer vote is an independent trial with a probability of 0.0005 of voting incorrectly.
Let X be the number of computers voting incorrectly. Since there are 4 independent computers, X can take on values 0, 1, 2, 3, and 4.
The probability mass function (PMF) for X is given by:
[tex]P(X = k) = \((4},{k) \times (0.0005)^k \times (0.9995)^{4-k}[/tex]
where C(4, k) = 4!/(k! * (4-k)!).
To find the CDF, F(x), of X, we sum the probabilities for all values up to x:
F(0) = P(X=0)F(1) = P(X=0) + P(X=1)F(2) = P(X=0) + P(X=1) + P(X=2)F(3) = P(X=0) + P(X=1) + P(X=2) + P(X=3)F(4) = P(X=0) + P(X=1) + P(X=2) + P(X=3) + P(X=4)Using the binomial probability formula, calculate each PMF and its cumulative sum to get the CDF:
F(0) = (0.9995)⁴[tex]F(1) = F(0) + 4 \times 0.0005 \times (0.9995)^3[/tex][tex]F(2) = F(1) + 6 \times (0.0005)^2 \times (0.9995)^2[/tex][tex]F(3) = F(2) + 4 \times (0.0005)^3 \times (0.9995)[/tex][tex]F(4) = F(3) + (0.0005)^4[/tex]Hence, the CDF of X encompasses a step-by-step summation of the binomial probabilities up to the desired value.
a fair die is tossed. A is the event that the outcome is odd. B is the event that the outcome is even. C is the event that the outcome is ess than 4.
Answer:
The question is incomplete. Below is the complete question
"A fair die is tossed. A is the event that the outcome is odd. B is the event that the outcome is even. C is the event that the outcome is less than 4. Determine P(A), P(B), P(C), P(A∩B), P(B∩C), P(A|B), P(A|C), P(B|C).
answers:
a.1/2
b. 1/2
c. 1/2
d.0
e. 1/6
f. 0
g. 2/3
h. 1/3
Step-by-step explanation:
lets write out the probability of each event
a.A=outcome is odd
A={1,3,5}
P(A)=1/2
b.B=outcome is even
B={2,4,6}
P(B)=1/2
c. C=outcome is less than 4
C={1,2,3}
P(C)=1/2
d.P(AnB)={its odd and even i.e what is common between set A and B}
Therefore, P(AnB) is a null set i.e P(AnB)={ }=0
e. BnC= {2} i.e elements common between set B and C
Hence P(BnC)=1/6
f. P{A|B}= P(AnB)/P(B) since P(AnB)=0, P(B)=1/2. then, P(A|B)=0
g. P(A|C)= P(AnC)/P(C) since P(AnC)=1/3, P(C)=1/2. therefore, P(A|C)=2/3
h. P(B|C)= P(BnC)/P(C), since P(BnC)=1/6, P(C)=1/2. therefore, P(B|C)=1/3
A student has to take twelve hours of classes a week. Due to her extracurricular activities, she must take at least three hours of classes on Monday, at least two on Tuesday, and at least one on Friday. In how many ways can she do this
The student has 210 ways to schedule the remaining six hours of classes across the week, after meeting specific daily minimum class hour requirements.
The student wants to schedule twelve hours of classes across a week while meeting minimum class hour requirements on specific days.
Monday requires at least three hours, Tuesday at least two, and Friday at least one hour of classes.
Considering the constraints, we must calculate the number of ways she can distribute her remaining class hours across the week.
Steps to Calculate the Distribution:
Determine the total hours already allocated due to constraints: 3 (Monday) + 2 (Tuesday) + 1 (Friday) = 6 hours.Subtract the allocated hours from the total required hours to find the remaining hours to be distributed: 12 total hours - 6 allocated hours = 6 hours remaining.Assuming the remaining six hours can be distributed among the five weekdays, the problem becomes a partitioning problem, where we need to find the number of ways to partition six hours into five parts (days), where a part could be zero, indicating no class on that day.Use the formula for partitions of n into k parts: P(n+k-1,k) which is equivalent to C(n+k-1, k-1) where C represents combination.Calculate the number of combinations: C(6+5-1,5-1) = C(10,4).Evaluate the combination: C(10,4) = 10! / (4!(10-4)!) = 210 ways.Therefore, the student has 210 ways to schedule the remaining six hours of classes across the week.
Find the probability for the experiment of tossing a coin three times. Use the sample space S = {HHH, HHT, HTH, HTT, THH, THT, TTH, TTT}.
1. The probability of getting exactly one tail
2. The probability of getting a head on the first toss
3. The probability of getting at least one head
4. The probability of getting at least two heads
Answer:
1) 0.375
2) 0.5
3) 0.875
4) 0.5
Step-by-step explanation:
We are given the following in the question:
Sample space, S = {HHH, HHT, HTH, HTT, THH, THT, TTH, TTT}.
[tex]\text{Probability} = \displaystyle\frac{\text{Number of favourable outcomes}}{\text{Total number of outcomes}}[/tex]
1. The probability of getting exactly one tail
P(Exactly one tail)
Favorable outcomes ={HHT, HTH, THH}
[tex]\text{P(Exactly one tail)} = \dfrac{3}{8} = 0.375[/tex]
2. The probability of getting a head on the first toss
P(head on the first toss)
Favorable outcomes ={HHH, HHT, HTH, HTT}
[tex]\text{P(head on the first toss)} = \dfrac{4}{8} = \dfrac{1}{2} = 0.5[/tex]
3. The probability of getting at least one head
P(at least one head)
Favorable outcomes ={HHH, HHT, HTH, HTT, THH, THT, TTH}
[tex]\text{P(at least one head)} = \dfrac{7}{8} = 0.875[/tex]
4. The probability of getting at least two heads
P(Exactly one tail)
Favorable outcomes ={HHH, HHT, HTH,THH}
[tex]\text{P(Exactly one tail)} = \dfrac{4}{8} = \dfrac{1}{2} = 0.5[/tex]
Final answer:
The question involves calculating probabilities based on the outcomes of tossing a coin three times. The probabilities for getting exactly one tail, a head on the first toss, at least one head, and at least two heads are found to be 3/8, 1/2, 7/8, and 1/2 respectively, by counting the favorable outcomes within the complete sample space.
Explanation:
The question asks for the probability of various outcomes when tossing a coin three times, given the sample space S = {HHH, HHT, HTH, HTT, THH, THT, TTH, TTT}. Let's solve each part step-by-step.
Probability of getting exactly one tail: There are three outcomes (HTT, THT, TTH) out of eight that satisfy this condition, so the probability is 3/8.
Probability of getting a head on the first toss: Four outcomes (HHH, HHT, HTH, HTT) satisfy this, so the probability is 4/8 or 1/2.
Probability of getting at least one head: Every outcome except TTT includes at least one head, so the probability is 7/8.
Probability of getting at least two heads: There are four outcomes (HHH, HHT, HTH, THH) that satisfy this condition, leading to a probability of 4/8 or 1/2.
Each probability is based on the fundamental principle of counting favorable outcomes over the total number of outcomes.
Find the probability for the experiment of drawing a card at random from a standard deck of 52 playing cards.
1. The card is a face card.
2. The card is not a face card.
3. The card is a red face card.
4. The card is a 6 or lower. (Aces are low.)
5. The card is a 9 or lower. (Aces are low.)
Answer:
1. 12/52 or 0.2308
2. 10/13 or 0.7692
3. 3/26 or 0.1154
4. 3/26 or 0.1154
5. 9/52 or 0.1731
Step-by-step explanation:
1.
The face card are king,queen and jack.
There are 12 face card in a deck of 52 cards i.e. 4 king, 4 queen and 4 jack.
P(FC)=12/52 or 0.2308
So, the probability that the card is a face card is 0.2308.
2.
The card is not a face card.
P(FC')=1-P(FC)=1-(12/52)=(52-12)/52=40/52=10/13
P(FC')=10/13 or 0.7692
So, the probability that the card is not a face card is 0.7692.
3.
The card is a red face card
There are 6 red face card in a deck of 52 cards i.e. 2 king, 2 queen and 2 jack.
P(RFC)=6/52
P(RFC)=3/26 or 0.1154
So, the probability that the card is a red face card is 0.1154.
4.
The card is a 6 or lower.
There are 6 cards in a deck of 52 cards that are 6 or lower i.e. 6,5,4,3,2 and ace.
P(6 or lower)=6/52
P(6 or lower)=3/26 or 0.1154
So, the probability that the card is a 6 or lower is 0.1154.
5.
The card is a 9 or lower.
There are 9 cards in a deck of 52 cards that are 9 or lower i.e. 9, 8, 7, 6, 5, 4, 3, 2 and ace.
P(9 or lower)=9/52
P(9 or lower)=9/52 or 0.1731
So, the probability that the card is a 9 or lower is 0.1731.
In a pack or deck of 52 playing cards, they are divided into 4 suits of 13 cards each i.e. spades , hearts , diamonds and clubs. King, Queen and Jack are face cards. So, there are 12 face cards in the deck of 52 playing cards.
In a Deck of 52 playing cards,
Number of face card = 12
number of non face card = 40
Number of red face card = 6
Number of Ace cards = 4
So, Probability of the card is face card is , = 12/52 =3/13
Probability of the card is not face card ,= 40/52 = 10/13
Probability of the card is a red face card is,=6/52 = 3/26
The probability of card is a 6 or lower is, = 24/52 = 6/13
The probability of card is a 9 or lower is, = 36/52 = 9/13.
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Determine (without solving the problem) an interval in which the solution of the given initial value problem is certain to exist. (Enter your answer using interval notation.) (t − 5)y' + (ln t)y = 6t, y(1) = 6
Answer:
0 < t < 5 is the required interval for the differential equation (t - 5)y' + (ln t)y = 6t to have a solution.
Step-by-step explanation:
Given the differential equation
(t - 5)y' + (ln t)y = 6t
and the condition y(1) = 6
We can rewrite the differential equation by dividing it by (t - 5) as
y' + [(ln t)/(t - 5)]y = 6t/(t - 5)
(ln t)/(t - 5) is continuous on the interval (0, 5) and (5, +infinity).
6t/(t - 5) is continuous on (-infinity, 5) and (5, +infinity)
We see that for these expressions, we have continuity at the intervals (0, 5) and (5, +infinity).
But the initial condition is y = 6, when t = 1.
The solution to differential equation is certain to exist at (0, 5)
Which implies that
0 < t < 5
is the required interval.
A person draws a five-card hand from a standard 52-card deck. If the order of the cards matters (i.e. ABCDE is a distinct hand from ABCED), use the Subtraction Principle to count how many hands contain at least one hearts card.
Answer:
242,784,360 hands.
Step-by-step explanation:
The number of hands that contain at least one hearts card is given by the total possible number of hands subtracted by the number of hands with no hearts card.
The total possible number of hands is:
[tex]N_T=\frac{52!}{(52-5)!}=\frac{52!}{(47)!} =52*51*50*49*48\\N_T=311,875,200[/tex]
Since there are 13 hearts cards in a deck, the number of possible hands with no hearts card is:
[tex]N_{H=0} =\frac{52-13!}{(52-13-5)!}=\frac{39!}{(34)!} =39*38*37*36*35\\N_{H=0}=69,090,840[/tex]
The number of hands with at least one hearts card is:
[tex]N_{H>0} = N_T-N{H=0}\\N_{H>0}=311,875,200-69,090,840\\N_{H>0}=242,784,360[/tex]
242,784,360 hands contain at least one hearts card.
1. A shipping company operates 10 container ships that can each carry 5000 containers on each journey between ports. They want to be able to load and unload 20,000 containers each week. Assume their ships always travel fully loaded. What is the longest average travel time between ports that allows them to meet their goal of 20,000 containers per week
Answer:
2.5 weeks
Step-by-step explanation:
Data provided in the question:
Number of container ships operated by the company = 10
Number of containers carried by each container = 5000
Number of container to be unloaded = 20,000
A shipping company operates 10 container ships
Now,
Capacity of 10 container ships = 10 × 5000 containers = 50,000 containers
Time required to load and upload 50,000 containers
= 50,000 containers ÷ 20,000 containers per week
= 2.5 weeks
Rapid HIV tests allow for quick diagnosis without expensive laboratory equipment. However, their efficacy has been called into question. In a population of 1517 tested individuals in Uganda, 4 had HIV but tested negative (false negatives), 166 had HIV and tested positive, 129 did not have HIV but tested positive (false positives), and 1218 did not have HIV and tested negative. A randomly slected person from this population tests negative for HIV. What is the probability that this person has HIV?
Answer:
The probability that a person has HIV given that the test negative is 0.0033.
Step-by-step explanation:
Denote the events as follows:
X = a person in Uganda had HIV
Y = a person in Uganda was tested positive for HIV.
The information provided is:
[tex]P(Y^{c}\cap X)=\frac{4}{1517}\\[/tex]
[tex]P(Y\cap X)=\frac{166}{1517}\\[/tex]
[tex]P(Y\cap X^{c})=\frac{129}{1517}\\[/tex]
[tex]P(Y^{c}\cap X^{c})=\frac{1218}{1517}\\[/tex]
The probability that a person has HIV given that he/she was tested negative is:
[tex]P(X|Y^{c})=\frac{P(Y^{c}\cap X)}{P(Y^{c})}[/tex]
Compute the probability of a person not having HIV as follows:
[tex]P(Y^{c})=P(Y^{c}\cap X)+P(Y^{c}\cap X^{c})=\frac{4}{1517}+\frac{1218}{1517} =\frac{4+1218}{1517} =\frac{1222}{1517}[/tex]
Compute the value of [tex]P(X|Y^{c})[/tex] as follows:
[tex]P(X|Y^{c})=\frac{P(Y^{c}\cap X)}{P(Y^{c})}=\frac{4}{1517}\times\frac{1517}{1222}=0.0033[/tex]
Thus, the probability that a person has HIV given that he/she was tested negative is 0.0033.
Final answer:
The probability that a randomly selected person from this population who tests negative actually has HIV is approximately 0.327%. This accounts for the possibility of false negatives. However, confirmatory testing is necessary to accurately diagnose HIV.
Explanation:
To calculate the probability that a randomly selected person from the population who tested negative for HIV actually has the virus, we need to focus on the false negatives and true negatives provided in the figures from Uganda.
Out of 1517 tested individuals, there were 4 false negatives and 1218 true negatives.
Thus, for someone who tests negative, to find out the probability that they actually have HIV (false negative), we use the formula: Probability = Number of false negatives / (Number of false negatives + Number of true negatives).
In this case, we have Probability = 4 / (4 + 1218) = 4 / 1222. When we calculate this probability, we get approximately 0.00327, or 0.327%.
Suppose that 30% of all students who have to buy a text for a particular course want a new copy (the successes!), whereas the other 70% want a used copy. Consider randomly selecting 15 purchasers.
(a) What are the mean value and standard deviation of the number who want a new copy of the book?(b) What is the probability that the number who want new copies is more than two standard deviations away from the mean value?
Answer:
a. Mean = 4.5, Standard Deviation = 1.775
b. 0.0152
Step-by-step explanation:
Given
n = 15 purchasers
p = Success = 30%
p = 0.3
q =Failure = 70%
q = 0.7
a.
Mean = np
Mean = 15 * 0.3
Mean = 4.5
Standard Deviation = √Variance
Variance = npq
Variance = 15 * 0.3 * 0.7
Variance = 3.15
Standard Deviation = √3.15
Standard Deviation = 1.774823934929884
Standard Deviation = 1.775 ---------- Approximated
b.
The probability that the number who want new copies is more than two standard deviations away from the mean value
Standard Deviation = 1.775
Mean = 4.5
2 Standard Deviation and Mean = 2 * 1.775 + 4.5
= 3.55 + 4.5
= 8.05
P(X>8.05) = P(9) + P(10) +........+ P(15)
Using the binomial distribution
(p + q) ^ n where p = 0.3, q = 0.7 , n = 15
Expanding (p+q)^n where n = 15 and r > 8
We have
15C9 p^9 q^6 + 15C10 p^10 q^5 + 15C11 p^11 q⁴ + 15C12 p^12 q³ + 15C13 p^13 q² + 15C14 p^14 q + p^15
= 5005 (0.3)^9 (0.7)^6 + 3003 (0.3)^10 (0.7)^5 + 1365 (0.3)^11 (0.7)⁴ + 455 (0.3)^12 (0.7)³ + 105 (0.3)^14 (0.7)² + 15 (0.3)^14 (0.7) + 0.3^15
=0.015234
At time, t, in seconds, your velocity, v, in meters/second, is given by v(t)=6+(t^2), 0 (=)t(=)6. Use (delta)t= 2 to estimate the distance traveled during this time.
Find the upper and lower estimates, and then average the two. find the upper estimate of distance traveled, find the lower estimate of distance traveled, and find the average.
Answer:
Total distance is 8 meters.
Step-by-step explanation:
First, let's take the equation and analyse it:
v(t) = 6 + t²
The delta t = 2
To find the acceleration, we need to differentiate v with respect to t like this:
dv/dt = d/dt (6 + t²)
= 2t
At t = 2, the change in velocity (dv/dt) = 2×2 = 4 m/s². This is the acceleration,a
The final velocity is given by v = 6 + (2)²
= 10 m/s
The distance is given by the formula:
s = ut + 1/2at²
initial velocity, u = 0
Therefore, the equation becomes s = 1/2at²
= 1/2× 4×4
= 8 m Ans
The upper estimate of the distance traveled is 150 meters, the lower estimate is 12 meters, and the average of these estimates is 81 meters.
Explanation:This math problem involves the concept of approximating the distance traveled using velocity and small intervals of time. The distance traveled, in approximation, can be calculated by taking the velocity at a certain time, and multiplying it by the change in time, which is given as 2 seconds in this case.
To find the upper estimate, we calculate using the endpoint of the interval, t = 6. To find the lower estimate, we calculate using the beginning of the interval, t = 0.
For upper estimate: v(6) x 2 = [6 + (6^2)] x 2 = 150 meters
For lower estimate: v(0) x 2 = [6 + (0^2)] x 2 = 12 meters
The average of the two estimates is then found by adding them together and dividing by 2, which results in 81 meters.
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A Web ad can be designed from four different colors, three font types, five font sizes, three images, and five text phrases. A specific design is randomly generated by the Web server when you visit the site. Let A denote the event that the design color is red and let B denote the event that the font size is not the smallest one. Use the addition rules to calculate the following probabilities.
P(AuB)
p(AuB')
P(A'uB')
Answer:
P(A∪B)=17/20 or 0.85
P(A∪B')=2/5 or 0.4
P(A'∪B')=4/5 or 0.8
Step-by-step explanation:
There are four font colors so each color had equal chance and thus,
P(A)=1/4
There are 5 font sizes and so not the smallest fonts are 4.Thus,
P(B)=4/5
P(A∪B)=P(A)+P(B)-P(A∩B)
The design is generated randomly so event A and event B are independent.
P(A∩B)=P(A)*P(B)
P(A∩B)=1/4(4/5)=1/5
P(A∪B)=P(A)+P(B)-P(A∩B)
P(A∪B)=1/4+4/5-1/5=1/4+3/5
P(A∪B)=17/20 or 0.85
P(A∪B')=P(A)+P(B')-P(A∩B')
P(B')=1-P(B)=1-4/5=1/5
P(A∩B')=P(A)*P(B')=1/4*1/5=1/20
P(A∪B')=P(A)+P(B')-P(A∩B')
P(A∪B')=1/4+1/5-1/20=9/20-1/20=8/20
P(A∪B')=2/5 or 0.4
P(A'∪B')=P(A∩B)'
P(A'∪B')=1-P(A∩B)
P(A'∪B')=1-1/5=4/5
P(A'∪B')=4/5 or 0.8
The probability of event A or B occurring can be calculated using the addition rule. The probability of A occurring is 1/4, the probability of B occurring is 4/5, and the probability of both A and B occurring is 1/5. Using the addition rule, the probability of A or B occurring is 13/20.
Explanation:To calculate the probability of events A or B occurring, we can use the addition rule. The addition rule states that the probability of A or B occurring is equal to the sum of their individual probabilities minus the probability that both A and B occur together.
First, let's calculate P(A): There are four possible colors, and one of them is red. So the probability of A, P(A), is 1/4. Next, let's calculate P(B): There are five possible font sizes, and the smallest size is not included in B. So the probability of B, P(B), is 4/5. Now, let's calculate P(A ∪ B): We need to account for the possibility that both A and B occur together. Since A and B are independent events, we can multiply their individual probabilities: P(A ∩ B) = P(A) * P(B) = (1/4) * (4/5) = 1/5. Finally, we can use the addition rule to calculate P(A ∪ B): P(A ∪ B) = P(A) + P(B) - P(A ∩ B) = 1/4 + 4/5 - 1/5 = 13/20. Learn more about Probability here:
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Find the distance from (3, −4, 8) to each of the following. (a) the xy-plane √7 (b) the yz-plane (0,−4,8) (c) the xz-plane (3,0,8) (d) the x-axis (3,0,0) (e) the y-axis (0,−4,0) (f) the z-axis (0,0,8)
Answer:
a) 8 units
b) 3 units
c) 4 units
d) [tex]4\sqrt{5}\text{ units}[/tex]
e) [tex]\sqrt{73}\text{ units}[/tex]
f) 5 units
Step-by-step explanation:
We are given the following:
Point (3, −4, 8)
We have to find the distance of the point from the following:
Distance formula:
[tex](x_1,y_1,z_1),(x_2,y_2,z_2)\\\\d = \sqrt{(x_2-x_1)^2 + (y_2-y_1)^2 + (z_2-z_1)^2}[/tex]
(a) the xy-plane
We have to find the distance from (3, −4, 8) to (3, −4, 0)
[tex]d = \sqrt{(3-3)^2 + (-4+4)^2 + (0-8)^2} = 8\text{ units}[/tex]
(b) the yz-plane
We have to find the distance from (3, −4, 8) to (0, −4, 8)
[tex]d = \sqrt{(0-3)^2 + (-4+4)^2 + (8-8)^2} = 3\text{ units}[/tex]
(c) the xz-plane
We have to find the distance from (3, −4, 8) to (3, 0, 8)
[tex]d = \sqrt{(3-3)^2 + (0+4)^2 + (8-8)^2} = 4\text{ units}[/tex]
(d) the x-axis
We have to find the distance from (3, −4, 8) to (3, 0, 0)
[tex]d = \sqrt{(3-3)^2 + (0+4)^2 + (0-8)^2} = \sqrt{80} = 4\sqrt{5}\text{ units}[/tex]
(e) the y-axis (0,−4,0)
We have to find the distance from (3, −4, 8) to (0, -4, 0)
[tex]d = \sqrt{(0-3)^2 + (-4+4)^2 + (0-8)^2} = \sqrt{73}\text{ units}[/tex]
(f) the z-axis (0,0,8)
We have to find the distance from (3, −4, 8) to (0, 0, 8)
[tex]d = \sqrt{(0-3)^2 + (0+4)^2 + (8-8)^2} = \sqrt{25} = 5\text{ units}[/tex]
A pack of Original Starbursts contains four colors/flavors: red (cherry), orange (orange), yellow (lemon), and pink (strawberry). A recent survey asked people what their favorite Starburst color (or flavor) is. They asked 756 people and recorded their favorite color (or flavor) and their age group. The table below provides the results:
What is your favorite Original Starburst color (flavor)? Oran Red (C 81 69 75 225 Group e) Yellow (Lemon Pink (Stra 124 121 114 359 Total 254 252 250 756 ildren (6-12 years old) Teenagers (13- 19 years old) 25 32 28 85 24 30 ng Adults (20 - 26 years old) otal 87
What is the probability that a randomly selected survey respondent is a Teenager OR selects Pink (Strawberry) as their favorite Starburts color (flavor)?
0.1601
0.1735
0.3333
0.4749
0.6481
0.6548
0.6667
Based on all your calculations, the events "a randomly selected person is a Teenager" and 'a randomly selected person selects Pink (Strawberry) as their favorite Starburst color (flavor)" would be considered (check all that applies):
dependent events
independent events
mutually exclusive events
complementary events
You could determine if the events "a randomly selected person is a Teenager" and "a randomly selected person selects Pink (Strawberry) as their favorite Starburst color (flavor)" were independent by comparing the P(Pink | Teenager) with which of the following probabilities?
0.1601
0.4560
0.4749
0.4882
0.5000
0.6481
0.6667
Answer:
P ( P U T ) = 0.6481
Dependent events
P ( P / T ) = (359/756) = 0.4749
Step-by-step explanation:
Given:
- Pink : P
- Teenagers: T
Find:
- P( T u P )
- Are the events T and R dependent, independent, mutually exclusive, or complementary
- If the events are independent, then we can compare P ( P / T ).
Solution:
a)
For first part we will determine the total outcome for T and P:
Total outcomes P or T = 359 + 252 - 121 = 490
(P U T) = (P) + (T) - (P n T)
The total number of possible outcomes are = 756
Hence, P ( P U T ) = 490 / 756 = 0.6481
b)
We are to investigate how the two events are related to one another:
- Check for dependent events:
P ( T n P ) = P( T ) * P ( P / T )
(121 / 756 ) = (252/756) * ( 121 / 252 )
(121 / 756) = (121/756) ....... Hence, events are dependent
- Check for independent events:
P ( T n P ) = P( T ) * P ( P )
(121 / 756 ) = (252/756) * ( 359 / 756 )
(121 / 756) =/ (359/756) ....... Hence, events are not independent
- Check for mutually exclusive events:
P ( T U P ) = P( T ) + P ( P )
(490 / 756 ) = (252/756) + ( 359 / 756 )
(121 / 756) =/ (611/756) ... Hence, events are not mutually exclusive
Hence, the two events are dependent on each other.
c)
If the events are said to be independent then the event:
P ( P / T ) = P (P)
P ( P / T ) = (359/756) = 0.4749
The probability that a randomly selected survey respondent is a Teenager OR selects Pink (Strawberry) as their favorite Starburst color (flavor) can be calculated by adding the individual probabilities of these two events occurring.
The probability of a respondent being a Teenager is 85/756, and the probability of selecting Pink (Strawberry) as their favorite flavor is 359/756. So, the probability of either event happening is (85/756) + (359/756) = 0.4749.
Based on these calculations, the events "a randomly selected person is a Teenager" and "a randomly selected person selects Pink (Strawberry) as their favorite Starburst color (flavor)" are NOT mutually exclusive events because they can both happen.
They are also NOT complementary events because they don't cover all possible outcomes.
Whether they are independent or dependent events can be determined by comparing P(Pink | Teenager) with the probability of Pink (Strawberry) regardless of age group, P(Pink).
If P(Pink | Teenager) is equal to P(Pink), they are independent events; otherwise, they are dependent.
In this case, P(Pink | Teenager) is 114/85, and P(Pink) is 359/756. Comparing these probabilities, we find that P(Pink | Teenager) is not equal to P(Pink), so the events are dependent.
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In 1998 the World Health Organization reported the findings of a major study on the quality of blood pressure monitoring around the world. In its report it stated that for Canada the results for diastolic blood pressure had a mean of 78 mmHg and a standard deviation of 11 mmHg. Assuming that diastolic blood pressure measurements are Normally distributed, the DBP reading that represents the 80th percentile of the distribution is _____.
Answer:
87.26 mm Hg is the reading that represents the 80th percentile of the distribution.
Step-by-step explanation:
We are given the following information in the question:
Mean, μ = 78 mm Hg
Standard Deviation, σ = 11 mm Hg
We are given that the distribution of diastolic blood pressure is a bell shaped distribution that is a normal distribution.
Formula:
[tex]z_{score} = \displaystyle\frac{x-\mu}{\sigma}[/tex]
We have to find the value of x such that the probability is 0.80
P(X < x)
[tex]P( X < x) = P( z < \displaystyle\frac{x - 78}{11})=0.8[/tex]
Calculation the value from standard normal z table, we have,
[tex]P(z < 0.842) = 0.8[/tex]
[tex]\displaystyle\dfrac{x - 78}{11} = 0.842\\\\x = 87.262 \approx 87.26[/tex]
87.26 mm Hg is the reading that represents the 80th percentile of the distribution.
To find the DBP reading representing the 80th percentile, we can use the z-score formula. The DBP reading is 86.8 mmHg.
Explanation:To find the diastolic blood pressure (DBP) reading that represents the 80th percentile of the distribution, we can use the z-score formula. The z-score is calculated by subtracting the mean from the desired value and dividing it by the standard deviation. Then, we can use the z-score table or calculator to find the corresponding percentile. In this case, since we want the 80th percentile, we need to find the z-score that corresponds to an area of 0.8 to the left of it.
The formula for the z-score is: z = (x - mean) / standard deviation
Using the given values for Canada (mean = 78 mmHg, standard deviation = 11 mmHg), we can substitute them into the formula and solve for x:
0.8 = (x - 78) / 11
Multiplying both sides by 11, we get:
8.8 = x - 78
Adding 78 to both sides, we get:
x = 86.8 mmHg
Therefore, the DBP reading that represents the 80th percentile of the distribution is 86.8 mmHg.
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How much work is required to lift a 1400-kg satellite to an altitude of 2⋅106 m above the surface of the Earth? The gravitational force is F=GMm/r2, where M is the mass of the Earth, m is the mass of the satellite, and r is the distance between the satellite and the Earth's center. The radius of the Earth is 6.4⋅106 m, its mass is 6⋅1024 kg, and in these units the gravitational constant, G, is 6.67⋅10−11.
To lift a 1400-kg satellite to an altitude of 2×10⁶ meters above the Earth's surface, the work required is approximately 2.079×10¹¹ Joules. This is calculated based on changes in gravitational potential energy using given values for mass, radius, and the gravitational constant.
To calculate the work required to lift a 1400-kg satellite to an altitude of 2×10⁶ meters (2000 km) above the Earth's surface, we need to consider the gravitational potential energy change.
Given:
Mass of the satellite (m): 1400 kgAltitude above Earth's surface (h): 2×10⁶ mRadius of the Earth (Rₑ): 6.4×10⁶ mMass of the Earth (M): 6×10²⁴ kgGravitational constant (G): 6.67×10⁻¹¹ N·m²/kg²The total distance from the center of the Earth to the satellite is:
r = Rₑ + h = 6.4×10⁶ m + 2×10⁶ m = 8.4×10⁶ m.The work required is equal to the change in gravitational potential energy:
The gravitational potential energy at a distance r from the Earth’s center is given by:
U = -GMm/rThe work done (W) to move the satellite from the Earth's surface to this altitude is the difference in potential energy:
W = GMm (1/Rₑ - 1/r)Substitute the given values:
W = (6.67×10⁻¹¹ N·m²/kg²)(6×10²⁴ kg)(1400 kg) [(1/6.4×10⁶ m) - (1/8.4×10⁶ m)]Calculate the values inside the brackets first:
(1/6.4×10⁶ - 1/8.4×10⁶) ≈ 1.5625×10⁻⁷ - 1.1905×10⁻⁷ ≈ 0.372×10⁻⁷Now, multiply:
W ≈ 6.67×10⁻¹¹ × 6×10²⁴ × 1400 × 0.372×10⁻⁷W ≈ 2.079×10¹¹ JoulesThe work required to lift the satellite to the desired altitude is approximately 2.079×10¹¹ Joules.
A statistics professor finds that when he schedules an office hour for student help, an average of 3.3 students arrive. Find the probability that in a randomly selected office hour, the number of student arrivals is 6.
Answer:
[tex] P(X=6)[/tex]
If we use the probability mass function we got:
[tex] P(X=6) = \frac{e^{-3.3} 3.3^6}{6!}= 0.0662[/tex]
Step-by-step explanation:
Previous concepts
The Poisson process is useful when we want to analyze the probability of ocurrence of an event in a time specified. The probability distribution for a random variable X following the Poisson distribution is given by:
Solution to the problem
Let X the random variable that represent the number of students arrive at the office hour. We know that [tex]X \sim Poisson(\lambda=3.3)[/tex]
The probability mass function for the random variable is given by:
[tex]f(x)=\frac{e^{-\lambda} \lambda^x}{x!} , x=0,1,2,3,4,...[/tex]
And f(x)=0 for other case.
For this distribution the expected value is the same parameter [tex]\lambda[/tex]
[tex]E(X)=\mu =\lambda=3.3[/tex]
And we want this probability:
[tex] P(X=6)[/tex]
If we use the probability mass function we got:
[tex] P(X=6) = \frac{e^{-3.3} 3.3^6}{6!}= 0.0662[/tex]
Answer:
0.0662
Step-by-step explanation:
The given problem indicates the Poisson experiment.
The pdf of Poisson experiment is as follow
P(X=x)=μ^x(e^-μ)/x!
Here, the average student visits in office hour=3.3=μ.
We have to find the probability that the number of student arrivals is 6 in a randomly selected office hour.
So, x=6 and μ=3.3
The probability that the number of student arrivals is 6 in a randomly selected office hour
P(X=6)=3.3^6(e^-3.3)/6!
P(X=6)=1291.468(.0369)/720
P(X=6)=47.6552/720
P(X=6)=0.0662.
Thus, the probability that the number of student arrivals is 6 in a randomly selected office hour is 6.62 or 0.0662.
If you bet $1 that a sum of 5 will turn up, what should the house pay (plus returning your $1 bet) if a sum of 5 turns up in order for the game to be fair?
Here is the complete question.
1). What are the odds for rolling a sum of 5 in a single roll of two fair dice?
2). If you bet $1 that a sum of 5 will turn up, what should the house pay (plus returning your $1 bet) if a sum of 5 turns up in order for the game to be fair?
Answer:
1). [tex]\frac{1}{8}[/tex]
2). $8.
Step-by-step explanation:
1).
The sample space (S) for rolling two fair dice is given as the following parameters illustrated below:
[tex]\left[\begin{array}{cccccc}(1,2)&(1,2)&(1,3)&(1,4)&(1,5)&(1,6)\\(2,1)&(2,2)&(2,3)&(2,4)&(2,5)&(2,6)\\(3,1)&(3,2)&(3,3)&(3,4)&(3,5)&(3,6)\end{array}\right] \left[\begin{array}{cccccc}(4,1)&(4,2)&(4,3)&(4,4)&(4,5)&(4,6)\\(5,1)&(5,2)&(5,3)&(5,4)&(5,5)&(5,6)\\(6,1)&(6,2)&(6,3)&(6,4)&(6,5)&(6,6)\end{array}\right][/tex]
Let F represent the event that the sum of both dice turns up is 5.
F = [(1,4),(2,3),(3,2),(4,1)}
∴ The probability for an event F is illustrated below as:
[tex]\frac{P(F)}{P(F')}[/tex] [tex]=\frac{\frac{4}{36} }{1-\frac{4}{36} }[/tex]
[tex]=\frac{\frac{4}{36} }{\frac{32}{36} }[/tex]
[tex]={\frac{4}{36}}*\frac{36}{32}[/tex]
= [tex]\frac{1}{8}[/tex]
2). From above, we can see that the probability for rolling a sum of 5 are 1 to 8. Therefore, if you roll a sum of 5, in order for the game to be fair, the house is required to pay $8.
Because of safety considerations, in May 2003 the Federal Aviation Administration (FAA) changed its guidelines for how small commuter airlines must estimate passenger weights. Under the old rule, airlines used 180 lb as a typical passenger weight (including carry-on luggage) in warm months and 185 lb as a typical weight in cold months. The Alaska Journal of Commerce (May 25, 2003) reported that Frontier Airlines conducted a study to estimate average passenger plus carry-on weights. They found an average summer weight of 183 lb and a winter average of 190 lb. Suppose that each of these estimates was based on a random sample of 100 passengers and that the sample standard deviations were 20 lb for the summer weights and 23 lb for the winter weights. A. Construct and interpret a 95% confidence interval for the mean summer weight (including carry-on luggage) of Frontier Airlines passengers.B. Construct and interpret a 95% confidence interval for the mean winter weight (including carry-on luggage) of Frontier Airlines passengers.C. The new FAA recommendations are 190 lb for sum- mer and 195 lb for winter. Comment on these recommen- dations in light of the confidence interval estimates from Parts (a) and (b).
Answer:
a) [tex]183-1.984\frac{20}{\sqrt{100}}=179.032[/tex]
[tex]183+1.984\frac{20}{\sqrt{100}}=186.968[/tex]
So on this case the 95% confidence interval would be given by (179.032;186.968)
b) [tex]190-1.984\frac{23}{\sqrt{100}}=185.437[/tex]
[tex]190+1.984\frac{23}{\sqrt{100}}=194.563[/tex]
So on this case the 95% confidence interval would be given by (185.437;194.563)
c) For Summer the confidence interval was (179.032;186.968) and as we can see our upper limit is <190 so then we can conclude that they are below the specification of 190 at 5% of significance
For Winter the confidence interval was (185.437;194.563) and again the upper limit is <190 so then we can conclude that they are below the specification of 195 at 5% of significance
Step-by-step explanation:
Previous concepts
A confidence interval is "a range of values that’s likely to include a population value with a certain degree of confidence. It is often expressed a % whereby a population means lies between an upper and lower interval".
The margin of error is the range of values below and above the sample statistic in a confidence interval.
Normal distribution, is a "probability distribution that is symmetric about the mean, showing that data near the mean are more frequent in occurrence than data far from the mean".
[tex]\bar X[/tex] represent the sample mean for the sample
[tex]\mu[/tex] population mean (variable of interest)
s represent the sample standard deviation
n represent the sample size
Part a : Summer
The confidence interval for the mean is given by the following formula:
[tex]\bar X \pm t_{\alpha/2}\frac{s}{\sqrt{n}}[/tex] (1)
In order to calculate the critical value [tex]t_{\alpha/2}[/tex] we need to find first the degrees of freedom, given by:
[tex]df=n-1=100-1=99[/tex]
Since the Confidence is 0.95 or 95%, the value of [tex]\alpha=0.05[/tex] and [tex]\alpha/2 =0.025[/tex], and we can use excel, a calculator or a table to find the critical value. The excel command would be: "=-T.INV(0.025,99)".And we see that [tex]t_{\alpha/2}=1.984[/tex]
Now we have everything in order to replace into formula (1):
[tex]183-1.984\frac{20}{\sqrt{100}}=179.032[/tex]
[tex]183+1.984\frac{20}{\sqrt{100}}=186.968[/tex]
So on this case the 95% confidence interval would be given by (179.032;186.968)
Part b: Winter
The confidence interval for the mean is given by the following formula:
[tex]\bar X \pm t_{\alpha/2}\frac{s}{\sqrt{n}}[/tex] (1)
In order to calculate the critical value [tex]t_{\alpha/2}[/tex] we need to find first the degrees of freedom, given by:
[tex]df=n-1=100-1=99[/tex]
Since the Confidence is 0.95 or 95%, the value of [tex]\alpha=0.05[/tex] and [tex]\alpha/2 =0.025[/tex], and we can use excel, a calculator or a table to find the critical value. The excel command would be: "=-T.INV(0.025,99)".And we see that [tex]t_{\alpha/2}=1.984[/tex]
Now we have everything in order to replace into formula (1):
[tex]190-1.984\frac{23}{\sqrt{100}}=185.437[/tex]
[tex]190+1.984\frac{23}{\sqrt{100}}=194.563[/tex]
So on this case the 95% confidence interval would be given by (185.437;194.563)
Part c
For Summer the confidence interval was (179.032;186.968) and as we can see our upper limit is <190 so then we can conclude that they are below the specification of 190 at 5% of significance
For Winter the confidence interval was (185.437;194.563) and again the upper limit is <190 so then we can conclude that they are below the specification of 195 at 5% of significance
Final answer:
Using statistical methods, we have constructed 95% confidence intervals for the mean summer and winter weights of Frontier Airlines passengers, finding that the new FAA recommendations align with our calculated intervals but are positioned conservatively towards the upper limits.
Explanation:
To answer the student's question about constructing and interpreting 95% confidence intervals for the mean summer and winter weights of Frontier Airlines passengers, and then commenting on the new FAA recommendations, we'll follow statistical methods.
Part A: Summer Weight
For the summer weight, the mean is 183 lb, the standard deviation is 20 lb, and the sample size (n) is 100 passengers. The formula for a 95% confidence interval is: mean ± (z*standard error), where the standard error is (standard deviation/√n). Using z=1.96 for 95% confidence, we calculate the interval as 183 ± (1.96*(20/√100)), which simplifies to 183 ± 3.92. Thus, the 95% confidence interval for summer is ±183 lb ± 3.92 lb.
Part B: Winter Weight
Similar calculations for the winter weight (mean = 190 lb, standard deviation = 23 lb, n = 100) yield a 95% confidence interval of 190 ± (1.96*(23/√100)), or 190 ± 4.51. Therefore, the 95% confidence interval for winter is ±190 lb ± 4.51 lb.
Part C: Comment on FAA Recommendations
The new FAA recommendations are 190 lb for summer and 195 lb for winter. These fall within our confidence intervals, but lean towards the upper limit, suggesting a conservative approach by the FAA, possibly to ensure safety by accommodating potential underestimations of passenger weights.
In a town there are on average 2.3 children in a family and a randomly chosen child has on average 1.6 siblings. Determine the variance of the number of children in a randomly chosen family.
The variance of the number of children in a randomly chosen family is approximately 9.4148.
To determine the variance of the number of children in a randomly chosen family, we can use the properties of the Poisson distribution, assuming that the number of children in a family follows a Poisson distribution with a mean of 2.3.
The Poisson distribution has a variance equal to its mean, so if the mean number of children per family is 2.3, then the variance is also 2.3.
However, we can also calculate the variance directly from the given information.
Let ( X ) be the random variable representing the number of children in a family.
Given:
- The mean number of children in a family, [tex]\( \mu = 2.3 \)[/tex]
- Each child has, on average, 1.6 siblings.
To find the variance, we use the formula:
\[ \text{Variance} = \text{E}(X^2) - [\text{E}(X)]^2 \]
[tex]First, we find \( \text{E}(X^2) \), the expected value of \( X^2 \):\[ \text{E}(X^2) = \text{Variance} + [\text{E}(X)]^2 \]\[ \text{E}(X^2) = 1.6^2 \times 2.3 + (2.3)^2 \]\[ \text{E}(X^2) = 4.096 \times 2.3 + 5.29 \]\[ \text{E}(X^2) = 9.4148 + 5.29 \]\[ \text{E}(X^2) = 14.7048 \][/tex]
Then, using the formula for variance:
[tex]\[ \text{Variance} = \text{E}(X^2) - [\text{E}(X)]^2 \]\[ \text{Variance} = 14.7048 - (2.3)^2 \]\[ \text{Variance} = 14.7048 - 5.29 \]\[ \text{Variance} = 9.4148 \][/tex]
So, the variance of the number of children in a randomly chosen family is approximately 9.4148.
Question:
In a town there are on average 2.3 children in a family and a randomly chosen child has on average 1.6 siblings. Determine the variance of the number of children in a randomly chosen family.
Explain the difference between the interquartile range and the range. Which is more sensitive to extreme values? Explain your thinking.
Answer:
Interquartile range: Difference between the third and the first quartile.
Range: Difference between the highest and the lowest value of a dataset.
Since the range is not in the middle of a set(like the quartiles), it is more sensitive to extreme values.
Step-by-step explanation:
The interquartile range is the difference between the third quartile and the first quartile.
The first quartile(Q1) separates the lower 25% from the upper 75% of a set. So 25% of the values in a data set lie at or below the first quartile, and 75% of the values in a data set lie at or above the first quartile.
The third quartile(Q3) separates the lower 75% from the upper 25% of a set. So 75% of the values in a data set lie at or below the third quartile, and 25% of the values in a data set lie at or the third quartile.
The range is the difference between the highest and the lowest value of a dataset.
Lets see two different sets of cardinality 8
Set 1: 5,5,6,7,8,9,13,13
Range = 13-5 = 8
Q1 = Element at the position 0.25*8 = 2 = 5
Q3 = Element at the position 0.75*8 = 6 = 9
IQR = Q3 - Q1 = 9 - 5 = 4
Now, replacing the first and the last element by extreme values
Set 1: 0,5,6,7,8,9,13,20
Range = 20-0 = 20
Q1 = Element at the position 0.25*8 = 2 = 5
Q3 = Element at the position 0.75*8 = 6 = 9
IQR = Q3 - Q1 = 9 - 5 = 4
The range changes and the IQR does not. Since extreme values are not in the middle of the distribution(in which the quartiles are), the range is more sensitive to extreme values, as this example showed.
Final answer:
The interquartile range measures the spread of the middle 50% of data and is less sensitive to extreme values compared to the range, which measures the spread of all data points by looking at the difference between the maximum and minimum values.
Explanation:
Difference Between Interquartile Range and Range in Data Analysis:
The difference between the interquartile range (IQR) and the range is that while the range measures the spread of all data points by subtracting the smallest value from the largest, the interquartile range measures the spread of the middle 50% of data, between the 25th and 75th percentiles (Q1 and Q3 respectively). To calculate the range in a dataset, if the highest score is 100 and the lowest is 70, the range is 100 - 70 = 30. On the other hand, if Q1 is 72.25 and Q3 is 86.75, the interquartile range would be 86.75 - 72.25 = 14.50.
The range is more sensitive to extreme values or outliers because it takes into account the most extreme scores in the dataset. In contrast, the IQR is less sensitive to extreme values since it focuses on the central portion of the data set and ignores the extremes. This is why IQR is often used to identify potential outliers, which are suspected if they lie more than 1.5 times the IQR below Q1 or above Q3.
Therefore, the IQR provides a more robust measure of data variability, especially when dealing with skewed distributions or datasets with outliers.
Three students were applying to the same graduate school. They came from schools with different grading systems. Student GPA School Average GPA School Standard Deviation Thuy 2.7 3.2 0.8 Vichet 88 75 20 Kamala 8.8 8 0.4 Which student had the best GPA when compared to other students at his school? Explain how you determined your answer. (Enter your standard deviation to two decimal places.) had the best GPA compared to other students at his school, since his GPA is standard deviations
Answer:
Kamala had the best GPA compared to other students at his school, since his GPA is 2 standard deviations above his school's mean.
Step-by-step explanation:
The z-score measures how many standard deviation a score X is above or below the mean.
it is given by the following formula:
[tex]Z = \frac{X - \mu}{\sigma}[/tex]
In which
[tex]\mu[/tex] is the mean, [tex]\sigma[/tex] is the standard deviation.
In this problem:
The student with the best GPA compared to other students at his school is the one with the higher z-score, that is, the one whose grade is the most standard deviations above the mean for his school
Thuy
Student GPA| School Average GPA| School Standard Deviation
Thuy 2.7| 3.2| 0.8
So [tex]X = 2.7, \mu = 3.2, \sigma = 0.8[/tex]
[tex]Z = \frac{X - \mu}{\sigma}[/tex]
[tex]Z = \frac{2.7 - 3.2}{0.8}[/tex]
[tex]Z = -0.625[/tex]
Thuy's score is -0.625 standard deviations below his school mean.
Vichet
Student GPA| School Average GPA| School Standard Deviation
Vichet 88| 75| 20
So [tex]X = 88, \mu = 75, \sigma = 20[/tex]
[tex]Z = \frac{X - \mu}{\sigma}[/tex]
[tex]Z = \frac{88 - 75}{20}[/tex]
[tex]Z = 0.65[/tex]
Vichet's score is 0.65 standard deviation above his school mean
Kamala
Student GPA| School Average GPA| School Standard Deviation
Kamala 8.8| 8| 0.4
So [tex]X = 8.8, \mu = 8, \sigma = 0.4[/tex]
[tex]Z = \frac{X - \mu}{\sigma}[/tex]
[tex]Z = \frac{8.8 - 8}{0.4}[/tex]
[tex]Z = 2[/tex]
Kamala's score is 2 standard deviations above his school mean.
Kamala has the higher z-score, so he had the best GPA when compared to other students at his school.
The correct answer is:
Kamala had the best GPA compared to other students at his school, since his GPA is 2 standard deviations above his school's mean.
Final answer:
Kamala had the best GPA relative to her school's average, with a z-score of 2.00, indicating her GPA is 2 standard deviations above the average.
Explanation:
To determine which student had the best GPA compared to other students at their school, we need to calculate how many standard deviations each student's GPA is away from their school's average GPA. This can be done using the formula:
z = (x - μ) / σ
Where z is the number of standard deviations, x is the student's GPA, μ (mu) is the school's average GPA, and σ (sigma) is the school's standard deviation.
Kamala has the highest z-score, which means her GPA is the furthest above her school's average when compared to Thuy and Vichet. Therefore, Kamala had the best GPA relative to her peers at her school.
The atmospheric pressures at the top and the bottom of a mountain are read by a barometer to be 93.8 and 100.5 kPa. If the average density of air is 1.25 kg/m3 , what is the height of the mountain
Answer:
546.94 meters is the height of the mountain.
Step-by-step explanation:
Pressure at the top of mountain = [tex]P_1=93.8 kPa[/tex]
Pressure at the bottom of the mountain = [tex]P_2=100.5 kPa[/tex]
Pressure difference =[tex]P_2-P_1=100.5kPa-93.8kPa=6.7 kPa[/tex]
6.7 kPa = 6.7 × 1000 Pa (1 kPa= 1000 pa)
Density of the air = d = [tex]1.25 kg/m^3[/tex]
Acceleration due to gravity = g = [tex]9.8 m/s^2[/tex]
Height of the mountain = h
[tex]P=h\times d\times g[/tex]
[tex]h=\frac{P}{d\times g}=\frac{6.7\times 1000 Pa}{1.25 kg/m^3\times 9.8 m/s^2}[/tex]
[tex]h=546.94 m[/tex]
546.94 meters is the height of the mountain.
A group of students estimated the length of one minute without reference to a watch or clock, and the times (seconds) are listed below. Use a 0.10 significance level to test the claim that these times are from a population with a mean equal to 60 seconds. Does it appear that students are reasonably good at estimating one minute? 75 88 51 73 49 31 69 74 72 59 72 81 99 101 73 What are the null and alternative hypotheses? A. Upper H 0: muequals60 seconds Upper H 1: munot equals60 seconds B. Upper H 0: munot equals60 seconds Upper H 1: muequals60 seconds C. Upper H 0: muequals60 seconds Upper H 1: muless than60 seconds D. Upper H 0: muequals60 seconds Upper H 1: mugreater than60 seconds Determine the test statistic. nothing (Round to two decimal places as needed.) Determine the P-value. nothing (Round to three decimal places as needed.) State the final conclusion that addresses the original claim. ▼ Fail to reject Reject Upper H 0. There is ▼ sufficient not sufficient evidence to conclude that the original claim that the mean of the population of estimates is 60 seconds ▼ is is not correct. It ▼ appears does not appear that, as a group, the students are reasonably good at estimating one minute.
Answer:
It does not appear that, as a group, the students are reasonably good at estimating one minute.
Step-by-step explanation:
We are given the following data in the question:
75, 88, 51, 73, 49, 31, 69, 74, 72, 59, 72, 81, 99, 101, 73
Formula:
[tex]\text{Standard Deviation} = \sqrt{\displaystyle\frac{\sum (x_i -\bar{x})^2}{n-1}}[/tex]
where [tex]x_i[/tex] are data points, [tex]\bar{x}[/tex] is the mean and n is the number of observations.
[tex]Mean = \displaystyle\frac{\text{Sum of all observations}}{\text{Total number of observation}}[/tex]
[tex]Mean =\displaystyle\frac{1067}{15} = 71.13[/tex]
Sum of squares of differences = 4739.733
[tex]S.D = \sqrt{\frac{4739.733}{14}} = 18.39[/tex]
Population mean, μ = 60 minutes
Sample mean, [tex]\bar{x}[/tex] = 71.13 minutes
Sample size, n = 15
Alpha, α = 0.10
Sample standard deviation, s = 18.39 minutes
First, we design the null and the alternate hypothesis
[tex]H_{0}: \mu = 60\text{ minutes}\\H_A: \mu \neq 60\text{ minutes}[/tex]
We use Two-tailed t test to perform this hypothesis.
Formula:
[tex]t_{stat} = \displaystyle\frac{\bar{x} - \mu}{\frac{s}{\sqrt{n}} }[/tex]
Putting all the values, we have
[tex]t_{stat} = \displaystyle\frac{71.13 - 60}{\frac{18.39}{\sqrt{15}} } = 2.34[/tex]
Calculating the p-value from the table, we have,
P-value = 0.034354
Since the p-value is lower than the significance level, we fail to accept the null hypothesis and reject it. We accept the alternate hypothesis.
Thus, we conclude that it does not appear that, as a group, the students are reasonably good at estimating one minute.
Option A is the correct set of hypotheses for testing if students can estimate one minute. The test statistic and p-value are needed to make a decision, typically using a t-test. The conclusion depends on the p-value relative to the significance level.
The null and alternative hypotheses you are working with for testing whether students are good at estimating one minute are:
H0: \\(\mu = 60\\) seconds - This states that the true population mean estimation time is 60 seconds.Ha: \\(\mu \not= 60\\) seconds - This hypothesis asserts that the true population mean estimation time is not 60 seconds.To determine if students are good at estimating one minute, we have option A as correct, which is H0: \\(\mu = 60\\) and Ha: \\(\mu \not= 60\\).
The test statistic and p-value should be calculated using appropriate statistical methods (typically a t-test assuming we do not know the population standard deviation, which would require the mean, standard deviation, and sample size). After calculating the test statistic and p-value, you will compare the p-value to the significance level (alpha). If the p-value is less than alpha, you reject H0; otherwise, you fail to reject H0.
Based on the decision to reject or fail to reject H0, you can make a conclusion regarding the original claim about whether students are reasonably good at estimating one minute.
Determine whether the series is convergent or divergent. 1 2 3 4 1 8 3 16 1 32 3 64 convergent divergent Correct:
The given series is an alternating harmonic series. It is convergent because the sequence of absolute values decreases to zero.
Explanation:The given series is: 1/2 , 3/4 , 1/8 , 3/16 , 1/32 , 3/64 . . . As you can see, the numerator alternates between 1 and 3, while the denominator doubles each time. This type of series is known as an alternating harmonic series.
To determine if an alternating series converges or diverges, we can apply the Alternating Series Test. This test says that an alternating series converges if the sequence of absolute values decreases to zero. In our case, the absolute value of the terms based solely on the denominator is decreasing to zero, hence, the series converges.
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Genome expression profiles and drug design: reseracher are trying to design a druq that alters the expression level of the three genes in a specific way. The desired change in expression, written as a vector in V3 is [3,9,-5], where all measurment are dimentionless. suppose two potential drugs are being studied, and the expression profiles that they induce are (A) [2,4,1] and (B) [-2,3,-5]. (a) What is the magnitude of the desired change in expression? (b) USing scalar projections, determine the fraction of this desired change that is induced by each drug. (c) Which drug is closest to having the desired effect?
Answer:
a) Magnitude = 10.72
b) = 0.32 and 0.400
c) Drug B is closest to having the desired effect.
Step-by-step explanation:
The knowledge of vector projection and dot product is applied as shown in the step by step explanation from the attached file.
This person has a 75% chance of a full recovery. Is this classical probability, empirical or subjective
Answer:
Subjective probability
Step-by-step explanation:
At first we should know the following:
Classical probability ⇒ when there are n equally likely outcomes.
Subjective probability ⇒ is based on whatever information is available.
Empirical probability ⇒ when the number of times the event happens is divided by the number of observations.
So, according to the previous definitions:
This person has a 75% chance of a full recovery
There is no equally likely outcomes, and the percentage of full recovery is based on the information available about the person and also it is based on educated guess.
So, this is Subjective probability
Three identical fair coins are thrown simultaneously until all three show the same face. What is the probability that they are thrown more than three times?
Answer:
The probability that the coins are thrown more than three times to show the same face is 0.3164.
Step-by-step explanation:
The problem is related to Geometric distribution.
The Geometric distribution defines the probability distribution of X failures before the first success.
The probability distribution function is:
[tex]P(X=k)=(1-p)^{k}p;\ k = 0, 1, 2, ...[/tex]
First compute the probability that in the [tex]i^{th}[/tex] throw all the three coins will show the same face.
P (All the 3 coins shows the same face) = P (All the three coins shows Heads) + P (All the three coins shows Tails)
[tex]=(\frac{1}{2}\times \frac{1}{2}\times \frac{1}{2} )+(\frac{1}{2}\times \frac{1}{2}\times \frac{1}{2} )\\=\frac{1}{8}+\frac{1}{8}\\ =\frac{2}{8} \\=\frac{1}{4}[/tex]
Now compute the probability that it takes more than 3 throws for the coins to show the same face.
P (X > 3) = 1 - P (X ≤ 3)
[tex]=1-[P(X=1)+P(X=2)+P(X=3)]\\=1-[[(1-\frac{1}{4} )^{0}\times\frac{1}{4}]+[(1-\frac{1}{4} )^{1}\times\frac{1}{4}]+ [(1-\frac{1}{4} )^{2}\times\frac{1}{4}]+[(1-\frac{1}{4} )^{3}\times\frac{1}{4}]]\\=1-[0.2500+0.1875+0.1406+0.1055]\\=1-0.6836\\=0.3164[/tex]
Thus, the probability that it takes more than 3 throws for the coins to show the same face is 0.3164.
The probability that it takes more than 3 throws for the coins to show the same face is 0.3164.
What is probability?Probability means possibility. It deals with the occurrence of a random event. The value of probability can only be from 0 to 1. Its basic meaning is something is likely to happen. It is the ratio of the favorable event to the total number of events.
Given
Three identical fair coins are thrown simultaneously until all three show the same face.
Then the total event will be
[tex]\rm Total \ event = 2^3 = 8[/tex]
All the possibilities.
[tex]\rm (HHH),( HHT ),(HTH),( THH),(HTT),(THT),(TTH),(TTT)[/tex]
For getting the same face, then the probability will be
[tex]\rm P(same\ face) = \dfrac{2}{8} = \dfrac{1}{4}[/tex]
Now compute the probability that it takes more than 3 throws for the coins to show the same face.
[tex]\rm P (X > 3) = 1 - P (X ≤ 3)\\\\P (X > 3) = 1 -[P(x=1) +P(x=2) + P(x=3)]\\\\P (X > 3) =1 -\{[(1-\dfrac{1}{4})^0 * \dfrac{1}{4}] +[(1-\dfrac{1}{4})^1 * \dfrac{1}{4}] +[(1-\dfrac{1}{4})^2 * \dfrac{1}{4}] +[(1-\dfrac{1}{4})^3 * \dfrac{1}{4}] \}\\\\P (X > 3) =1 - 0.6836\\\\P (X > 3) =0.3164[/tex]
Thus, the probability that it takes more than 3 throws for the coins to show the same face is 0.3164.
More about the probability link is given below.
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At least 96.00% of the data in any data set lie within how many standard deviations of the mean? Explain how you arrived at your answer.
At least 96.00% of the data in any data set lies within three standard deviations of the mean.
Explanation:The Empirical Rule states that in a bell-shaped and symmetric distribution, approximately 68 percent of the data lies within one standard deviation of the mean, 95 percent lies within two standard deviations of the mean, and more than 99 percent lies within three standard deviations of the mean. Therefore, at least 96.00% of the data lies within three standard deviations of the mean.
how many pounds of bananas cost $3.75
Answer:
you go up by .75 each time per pound so it would be 5 pounds.
hope this helps!!
Answer:
5
Step-by-step explanation:
Or (A)
What will be the cost of gasoline for a 4,700-mile automobile trip if the car gets 41 miles per gallon, and the average price of gas is $2.79 per gallon?
$ 320
Step-by-step explanation:41 miles ............ 1 gallon
4700 miles .......x gallon
x = 4700×1/41 = 114.63 gallons
114.63 gallons×$2.79 ≈ $ 320
To find the cost of gasoline for a 4,700-mile automobile trip, divide the total distance by the car's miles per gallon, then multiply by the price of gas per gallon, finally we get a total cost of $318.65.
Explanation:To find the cost of gasoline for a 4,700-mile automobile trip, we need to divide the total distance by the car's miles per gallon to get the number of gallons of gas needed.
Then, we multiply the number of gallons by the price of gas per gallon to get the total cost.
In this case, the car gets 41 miles per gallon, so the number of gallons needed is 4700 miles / 41 miles per gallon = 114.63 gallons.
Multiplying this by the average price of gas, $2.79 per gallon, we get a total cost of $318.65.
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