Determine whether or not the random variable X is a binomial random variable. If so, give the values of n and p. If not, explain why not. a. X is the number of dots on the top face of fair die that is rolled. b. X is the number of defective parts in a sample of ten randomly selected parts coming from a manufacturing process in which 0.02% of all parts are defective.

Answer:

Step-by-step explanation:

Demand = 19,500 units per year (D)

Ordering cost = $25 per order (O)

Holding cost = $4 per unit per year (C)

a) [tex]EOQ=\sqrt{ \frac{2\times D\times O}{C}}[/tex]

   [tex]EOQ=\sqrt{ \frac{2\times 19,500\times 25}{4}}[/tex]

   = [tex]\sqrt{\frac{975000}{4}}[/tex]

   = [tex]\sqrt{243,750}[/tex]

   = 493.71044 ≈ 494

b) Annual holding cost = [tex]4\times(\frac{Q}{2})[/tex]

                                      = [tex]4\times(\frac{494}{2})[/tex]

                                      = 4 × 247

                                      = 988

c) Annual ordering cost = [tex]O\times(\frac{D}{Q} )[/tex]

                                       = [tex]25\times(\frac{19,500}{494} )[/tex]

                                       = 25 × 39.47

                                       = 986.75

AOQ = 494

Annual holding cost = 988

Annual ordering cost = 986.75

Answer:

H ₀ : p ≤ 0.25

H ₁: p > 0.25

Test statics value  z = 12.91

Decision Rule:

Reject the value of null hypothesis

Conclusion:

If survey is online then there is sufficient evidence to claim . If the sample is  voluntary response sample then conclusion is not valid.

Step-by-step explanation:

step by step explanation is shown in attachment.

Answer:

12%

Step-by-step explanation:

The probability that the residents of a household do not own two cars and have an income over $50,000 a year is 100% subtracted by the probability of owning two cars and having an income over $50,000(P(2∩50+) and the probability of not having an income over $50,000 (P(50-))

[tex]P = 1 - P(2\cap 50+) - P(50-)\\P = 1 - (0.6*0.7) - (1-0.6)\\P=1-0.48-0.40\\P=0.12[/tex]

Therefore, the probability that the residents of a household do not own two cars and have an income over $50,000 a year is 12%

Final answer:

To find the probability that a household has an income over $50,000 and does not own two cars, multiply the probability of a household not owning two cars (20%) by the probability of having an income over $50,000 (60%), which equals 12%.

Explanation:

The question is asking us to find the probability that the residents of a household do not own two cars and have an income over $50,000 a year. We know that the probability a household with income over $50,000 owns two cars is 80%, so the probability that such a household does not own two cars is 1 - 0.80 = 0.20 or 20%. Since 60% of households have an income over $50,000, we can calculate the probability that a household has an income over $50,000 and does not own two cars by multiplying these two probabilities: 0.60 * 0.20 = 0.12 or 12%.

There are 125,970 ways to select the players who will travel to an away game. There are 79,833,600 ways to select the starting line-up. With a restriction on the center position, there are 12 ways to select the starting line-up.

(a) The coach must select 12 players to travel to an away game:

There are 20 members on the basketball team, and the coach needs to select 12 players to travel. This is a combination problem, since the order doesn't matter. The formula for calculating combinations is: nCr = n! / (r! * (n-r)!), where n is the total number of players and r is the number of players to be selected.

Using this formula, we can calculate the number of ways to select the traveling players: 20C12 = 20! / (12! * (20-12)!) = 125,970 ways.

(b) The coach must select her starting line-up:

There are 12 players who will travel, and the coach needs to select 5 players for the starting line-up. This is a permutation problem, since the order does matter. The formula for calculating permutations is: nPr = n! / (n-r)!, where n is the total number of players and r is the number of players to be selected.

Using this formula, we can calculate the number of ways to select the starting line-up: 12P5 = 12! / (12-5)! = 12! / 7! =  79,833,600 ways.

(c) The coach must select her starting line-up, with a restriction on the center position:

There are 12 players who will travel, and only 3 players who can play center. The remaining 4 positions have no restrictions. We can calculate the number of ways to select the starting line-up by first selecting the center player (3 ways), and then selecting the players for the other positions (4P4 = 4 ways).

Therefore, the total number of ways to select the starting line-up with the restriction on the center position is: 3 * 4 = 12 ways.

The probability that the average income of a 41-person sample would be less than $42,000, given a population with mean annual income of $43,000 and a standard deviation of $29,000, is 0.4129.

This is a problem of probability concerning the Mean and Standard Deviation of the sampling distribution of the sample mean. We first have to find the Standard Error (SE) for the sampling distribution of the sample mean, which is given by SE = σ/√n , where σ is the standard deviation (29) and n is the sample size (41). Thus, SE = 29/√41 = 4.52.

Next, we find the Z score corresponding to the sample mean of 42. Z = (X - μ)/SE, where X is the sample mean (42), μ is the population mean (43), and SE is the standard error. So Z = (42 - 43)/4.52 = -0.22.

Looking up a Z score of -0.22 in a standard normal distribution table, we find a probability of 0.4129. Therefore, the answer is B) 0.4129.

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Final answer:

Using the Central Limit Theorem and provided statistics, the probability that the sample mean income is less than 42 thousand dollars is found by calculating a z-score and consulting standard normal distribution tables, resulting in a probability of 0.4129.

Explanation:

The task at hand is to calculate the probability that the sample mean income is less than 42 thousand dollars. Given the population mean (μ) of 43 thousand dollars and the standard deviation (σ) of 29 thousand dollars, with a sample size (n) of 41, we can use the Central Limit Theorem to determine that the sampling distribution of the sample mean will be normally distributed with a mean equal to the population mean and a standard deviation equal to the population standard deviation divided by the square root of the sample size.

To find the probability, we first calculate the standard error (SE), which is:

SE = σ / √n = 29 / √41 ≈ 4.53

We then calculate the z-score for the sample mean of 42 thousand dollars as:

Z = (X - μ) / SE = (42 - 43) / 4.53 ≈ -0.22

Using standard normal distribution tables or a calculator, the probability of a z-score being less than -0.22 is approximately 0.4129. Thus, the answer is B) 0.4129.

The standard deviation of returns is 2.82% by calculating expected value, variance and standard deviation.

Given that:

State of Economy Probability Rate of Return if State Occurs

Recession 0.22                         -0.9

Normal         0.47                                 0.105

Boom         0.31                                 0.215

To calculate the standard deviation of returns, by  using the formula:

Standard Deviation = [tex]\sqrt{}[/tex][Σ (Probability * (Rate of Return - Expected Return[tex])^2[/tex])]

Step 1: calculate the Expected Return: Multiply each rate of return by its corresponding probability and sum the results:

E = Σ(Rate of Return* Probability )

Plugging the given data gives:

E = (0.22 * -0.9) + (0.47 * 0.105) + (0.31 * 0.215)

On multiplication gives

E = 0.0225 - 0.04935 + 0.06665

On solving gives:

E = 0.0398.

Step 2: Calculate the Variance: For each rate of return, subtract the expected return, square the result, multiply by its corresponding probability, and sum the results:

Variance ( V) = Σ (Probability * (Rate of Return - Expected Return[tex])^2[/tex]

Plugging the given data gives:

[tex]V = [(0.22 * (-0.9 - 0.0398)^2) + (0.47 * (0.105 - 0.0398)^2) + (0.31 * (0.215 - 0.0398)^2)][/tex]

On squaring and solving gives:

[tex]V = [0.0225 + 0.02741 + 0.0412][/tex]

On adding gives:

[tex]V = 0.09111.[/tex]

Step3: Find the square root of the variance to get the Standard Deviation:

[tex]\sigma = \sqrt V[/tex]

Plugging the given data gives:

[tex]\sigma = \sqrt{0.09111 }[/tex]

On taking square root gives:

[tex]\sigma \approx 0.282[/tex] or 2.82%.

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Question:

Based on the following information, what is the standard deviation of returns?

State of Economy Probability Rate of Return if State Occurs

Recession 0.22                         -0.9

Normal         0.47                                 0.105

Boom         0.31                                 0.215

To calculate the standard deviation of returns, follow these steps: 1) Calculate the expected return for each state by multiplying the probability of the state occurring by the rate of return. 2) Calculate the squared difference between each state's return and the expected return. 3) Multiply each squared difference by the probability of the state occurring. 4) Sum up all the values obtained in step 3. 5) Take the square root of the sum obtained in step 4.

To calculate the standard deviation of returns, we need to follow these steps:

Using the given information:

Next, we calculate the squared difference between each state's return and the expected return:

Then, we multiply each squared difference by the probability of the state occurring:

Finally, we sum up all the values obtained:

And take the square root of the sum:

Therefore, the standard deviation of returns is approximately 0.0969.

Answer:   (1.1838, 1.1962)

Step-by-step explanation:

The formula we use to calculate the confidence interval for population mean ( if population standard deviation is not given)is given by :-

[tex]\overline{x}\pm t*\dfrac{s}{\sqrt{n}}[/tex],

where n= sample size

s= sample standard deviation.

[tex]\overline{x}[/tex]= sample mean

t* = Two-tailed critical t-value.

Given : n= 25

Degree of freedom : df = n-1 =24

Significance level [tex]=\alpha=1-0.95=0.95[/tex]

Now from students' t-distribution table , check the t-value for significance level [tex]\alpha/2=0.025[/tex] and df=24:

t*=2.0639

[tex]\overline{x}=1.19[/tex]  fluid ounces

s= 0.015  fluid ounces

We assume that the population is approximately normally distributed

Now, the 95% two-sided confidence interval on the mean volume of syrup dispensed :-

[tex]1.19\pm (2.0639)\dfrac{0.015}{\sqrt{25}}\\\\=1.19\pm (2.0639)(\dfrac{0.015}{5})\\\\=1.19\pm0.007728=(1.19-0.0061917,\ 1.19+0.0061917)\\\\=(1.1838083,\ 1.1961917)\approx(1.1838,\ 1.1962)[/tex]

∴ The required confidence interval = (1.1838, 1.1962)

To find the 95% two-sided confidence interval for the mean volume of syrup dispensed, use the t-distribution with the given sample mean, standard deviation, and size. The resulting interval is (1.183808, 1.196192) fluid ounces.

To calculate the 95% two-sided confidence interval for the mean volume of syrup dispensed, we can use the t-distribution, as the population standard deviation is unknown, and the sample size is less than 30.

Step-by-Step Explanation:

First, identify the sample mean (ar{x}), which is 1.19 fluid ounces, the sample standard deviation (s), which is 0.015 fluid ounces, and the sample size (n), which is 25.

Next, find the t-score that corresponds to a 95% confidence level and 24 degrees of freedom (n-1). You can use a t-distribution table or calculator for this, which typically gives you a t-score around 2.064.

Now calculate the margin of error (ME) using the formula ME = t*(s/sqrt{n}).

Finally, construct the confidence interval by adding and subtracting the margin of error from the sample mean: (1.19 - ME, 1.19 + ME).

Plugging in the values, we get ME = 2.064*(0.015/sqrt{25}) = 2.064*0.003 = 0.006192. So, the 95% confidence interval is (1.19 - 0.006192, 1.19 + 0.006192) = (1.183808, 1.196192).

Answer: The 95% confidence interval for the mean of x is (94.08, 101.92) .

Step-by-step explanation:

We are given that ,

A random variable x has a Normal distribution with an unknown mean and a standard deviation of 12.

i.e. [tex]\sigma= 12[/tex]

Also, it is given that , Sample mean [tex]\overline{x}=98[/tex] having sample size : n= 36

For 95% confidence ,

Significance level : [tex]\alpha=1-0.95=0.05[/tex]

By using the z-value table , the two-tailed critical value for 95% Confidence interval :

[tex]z_{\alpha/2}=z_{0.025}=1.96[/tex]

We know that the confidence interval for unknown population mean[tex](\mu)[/tex] is given by :-

[tex]\overline{x}\pm z_{\alpha/2}\dfrac{\sigma}{\sqrt{n}}[/tex]

, where [tex]\overline{x}[/tex] = Sample mean

[tex]\sigma[/tex] = Population standard deviation

[tex]z_{\alpha/2}[/tex] = Critical z-value.

Substitute all the given values, then the required confidence interval will be :

[tex]98\pm (1.96)\dfrac{12}{\sqrt{36}}[/tex]

[tex]=98\pm (1.96)\dfrac{12}{6}[/tex]

[tex]=98\pm (1.96)(2)[/tex]

[tex]=98\pm 3.92=(98-3.92,\ 98+3.92)\\\\=( 94.08,\ 101.92)[/tex]

Therefore, the 95% confidence interval for the mean of x is (94.08, 101.92) .

Answer:

0.5746

Step-by-step explanation:

Lets call X monthly bill chosen. X is a random variable with distribution N(μ=53,σ =15). We first standarize X, lets call W = (X-53)/15, random variable obtained from X by substracting μ and dividing by σ. W is a random variable with distribution N(0,1) and the cummulative function of W, Φ, is tabulated. You can find the values of Φ on the attached file. Using this information we obtain

[tex] P(47 < X < 74) = P(\frac{47-53}{15} < \frac{X-53}{15} < \frac{74-53}{15}) = P(-0.4 < W < 1.4) = \phi(1.4) - \phi(-0.4) [/tex]

A standard normal random variable has a symmetric density function, as a result Φ(-0.4) = 1- Φ(0.4) = 1- 0.6554 = 0.3446. Also, Φ(1.4) = 0.9192. We conclude that Φ(1.4)-Φ(-0.4) =  0.9192-0.3446 = 0.5746, that is the probability that the phone bill is between 47 and 74 euros.

Without the exact F-statistic and p-value, it is not possible to definitively choose between rejecting or failing to reject the null hypothesis. The decision would depend on whether the calculated p-value is less than the level of significance (0.10).

To determine whether there is a significant difference in the variance of grading procedures between two professors, we need to conduct an F-test for variance. The null hypothesis (H0) would be that there is no significant difference in the variances of grading, while the alternative hypothesis (H1) would be that there is a significant difference in the variances.

Using the data provided:

The F-statistic is calculated by dividing the variance of the set with the larger variance (squared standard deviation) by the variance of the set with the smaller variance, which means:

F = (22.4)^2 / (12.0)^2

However, the exact F value is not provided in the data, nor is the p-value. To make the decision, we would compare the p-value to the level of significance (
0.10). If the p-value is less than 0.10, we would reject the null hypothesis, indicating that there is a significant difference between the variances. If the p-value is greater than 0.10, we would fail to reject the null hypothesis, indicating there is no significant difference in variances.

Based on the options provided in the question, without the exact p-value or F-statistic, we cannot provide the correct answer. Thus, the answer would depend on the calculated p-value from the F-statistic. The options, therefore, are between A (rejecting the H0) or B (failing to reject the H0), and an exact answer requires additional information from an F-test.

Answer:

z= 5.08

The p value obtained was a very low value and using the significance level given [tex]\alpha=0.05[/tex] we have [tex]p_v<\alpha[/tex] so we can conclude that we have enough evidence to reject the null hypothesis, and we can said that at 5% of significance the proportion of adults who say's that it is morally wrong to not report all income on tax returns differs from 0.7 or 70% .

Step-by-step explanation:

1) Data given and notation

n=750 represent the random sample taken

X=589 represent the adults that said that it is morally wrong to not report all income on tax returns

[tex]\hat p=\frac{589}{750}=0.785[/tex] estimated proportion of adults that said that it is morally wrong to not report all income on tax returns

[tex]p_o=0.7[/tex] is the value that we want to test

[tex]\alpha=0.05[/tex] represent the significance level

Confidence=95% or 0.95

z would represent the statistic (variable of interest)

pv represent the p value (variable of interest)  

2) Concepts and formulas to use  

We need to conduct a hypothesis in order to test the claim that 70% of adults say that it is morally wrong to not report all income on tax returns.:  

Null hypothesis:[tex]p=0.7[/tex]  

Alternative hypothesis:[tex]p \neq 0.7[/tex]  

When we conduct a proportion test we need to use the z statisitc, and the is given by:  

[tex]z=\frac{\hat p -p_o}{\sqrt{\frac{p_o (1-p_o)}{n}}}[/tex] (1)  

The One-Sample Proportion Test is used to assess whether a population proportion [tex]\hat p[/tex] is significantly different from a hypothesized value [tex]p_o[/tex].

3) Calculate the statistic  

Since we have all the info requires we can replace in formula (1) like this:  

[tex]z=\frac{0.785 -0.7}{\sqrt{\frac{0.7(1-0.7)}{750}}}=5.08[/tex]  

4) Statistical decision  

It's important to refresh the p value method or p value approach . "This method is about determining "likely" or "unlikely" by determining the probability assuming the null hypothesis were true of observing a more extreme test statistic in the direction of the alternative hypothesis than the one observed". Or in other words is just a method to have an statistical decision to fail to reject or reject the null hypothesis.  

The significance level provided [tex]\alpha=0.05[/tex]. The next step would be calculate the p value for this test.  

Since is a bilateral test the p value would be:  

[tex]p_v =2*P(z>5.08)=0.000000377[/tex]  

So the p value obtained was a very low value and using the significance level given [tex]\alpha=0.05[/tex] we have [tex]p_v<\alpha[/tex] so we can conclude that we have enough evidence to reject the null hypothesis, and we can said that at 5% of significance the proportion of adults who say's that it is morally wrong to not report all income on tax returns differs from 0.7 or 70% .  

- Make an equation representing the number of vehicles needed.

We have six drivers so

x + y ≤ 6

That's not really an equation; it's an inequality.  We want to use all our drivers so we can use the small vans, so

x + y = 6

- Make an equation representing the total number of seats in vehicles for the orchestra members.

s = 25x + 12y

That's how many seats total; it has to be at least 111 so again an inequality,

25x + 12y ≥ 111

We solve it like a system of equations.  

x + y = 6

y = 6 - x

111 = 25x + 12y = 25x + 12(6-x)

111 = 25x + 72 - 12x

111 - 72 = 13 x

39 = 13 x

x = 3

Look at that,  it worked out exactly.  It didn't have to.

y = 6 - x = 3

Answer: 3 buses, 3 vans

Using a System of equations, the number of buses and vans required are 3 respectively.

Using the system of equations :

Total number of buses :

Total number of passengers :

From (1)

Substitute (3) into (2)

25(6-v) + 12v = 111

150 - 25v + 12v = 111

-13v = 111 - 150

-13v = - 39

v = 39/13

v = 3

From (3)

b = 6 - 3

b = 3

Hence, the number of vans and buses required are 3 and 3 respectively.

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Answer:

[tex]P(\bar X>530)=1-0.808=0.192[/tex]

Step-by-step explanation:

1) Previous concepts

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".

The Z-score is "a numerical measurement used in statistics of a value's relationship to the mean (average) of a group of values, measured in terms of standard deviations from the mean".  

Let X the random variable that represent the scores, and for this case we know the distribution for X is given by:

[tex]X \sim N(\mu=505,\sigma=170)[/tex]  

And let [tex]\bar X[/tex] represent the sample mean, the distribution for the sample mean is given by:

[tex]\bar X \sim N(\mu,\frac{\sigma}{\sqrt{n}})[/tex]

On this case  [tex]\bar X \sim N(505,\frac{170}{\sqrt{35}})[/tex]

2) Calculate the probability

We want this probability:

[tex]P(\bar X>530)=1-P(\bar X<530)[/tex]

The best way to solve this problem is using the normal standard distribution and the z score given by:

[tex]z=\frac{x-\mu}{\frac{\sigma}{\sqrt{n}}}[/tex]

If we apply this formula to our probability we got this:

[tex]P(\bar X >530)=1-P(Z<\frac{530-505}{\frac{170}{\sqrt{35}}})=1-P(Z<0.87)[/tex]

[tex]P(\bar X>530)=1-0.808=0.192[/tex]

Using the central limit theorem, the probability of a sample mean of 530 or more is calculated considering the distribution of the sample mean, which is approximately normal due to the sample size.

To calculate the probability that a sample of 35 exams will have a mean score of 530 or more, when the population mean is 505 with a standard deviation of 170, we use the concept of the sampling distribution of the sample mean. Since the sample size is 35, which is less than 10% of all psychology majors (assuming they number in the thousands), and the population distribution is normal or the sample size is large enough (which it is in this case), we can apply the Central Limit Theorem.

This theorem states that the sampling distribution of the sample mean will be approximately normally distributed with a mean equal to the population mean (μ = 505) and a standard deviation equal to σ/√n, where σ is the population standard deviation and n is the sample size (which is √35 in this case).

Country: Cultural issues, currency risks. Region: Land costs, air and rail systems. (Total: 10 words)

In assessing country and region success factors, certain variables hold significant weight. Country success factors encompass aspects such as cultural issues and currency risks, which directly influence a nation's economic stability and investment attractiveness.

Cultural nuances affect business practices and consumer behaviors, while currency risks impact trade competitiveness and profitability.

Conversely, region success factors pivot around considerations like land costs and transportation infrastructure, particularly air and rail systems. Land costs dictate the feasibility of establishing operations or acquiring property within a region, shaping investment decisions.

Meanwhile, efficient air and rail systems facilitate logistical operations and market access, enhancing the competitiveness of businesses located within the region.

These factors collectively contribute to a region's appeal for businesses seeking to establish or expand operations.

Thus, understanding and appropriately navigating these variables are crucial for organizations aiming to optimize their strategic positioning at both the national and regional levels, ensuring long-term success and sustainability in an increasingly complex global landscape.

The decision rule for rejecting the null hypothesis H₀ is

if t-statistic < -2.093.

First , let's state the null and alternative hypotheses:

Null hypothesis (H₀): The population mean weight of banana chips is 447 grams (the machine works correctly).

Alternative hypothesis (H₁): The population mean weight of banana chips is less than 447 grams (the machine is underfilling).

α = 0.025

Since this is a one-tailed test (we only care if the weight is less than 447 grams), we need to find the t-value for a single-tailed test with α = 0.025 and degrees of freedom (df) = n - 1 = 19 - 1 = 18.

We can use a t-distribution table or a statistical calculator to find this value. In most calculators, you can use the TINV function with df = 18, tails = 1, and p = 0.025. The critical value (t_α) is approximately -2.093.

Reject the null hypothesis (H₀) if the calculated t-statistic (t_stat) is less than the critical value (t_α). In other words, if the sample mean weight is significantly lower than 447 grams, we have evidence to suggest the machine is underfilling.

Reject H₀ if t_stat < -2.093.

This will require  sample data (the weights of the 19 bags). Once we have that, we can calculate the t-statistic using the formula:

t_stat = (sample mean - hypothesized mean) / (standard deviation / sqrt(sample size)).

The complete question is : A manufacturer of banana chips would like to know whether its bag filling machine works correctly at the 447 gram setting. It is believed that the machine is underfilling the bags. A 19 bag sample had a mean of 443 grams with a standard deviation of 21. A level of significance of 0.025 will be used. Assume the population distribution is approximately normal. Determine the decision rule for rejecting the null hypothesis. Round your answer to three decimal places.

Answer:

f(x) =4x² + x - 7

Step-by-step explanation:

f(x) = ax² + bx + c

f(1) = a + b + c

f(-3) = 9a - 3b + c

f(3) = 9a + 3b + c

a + b + c = -2 -----(1)

c = -2-a-b -----(2)

9a - 3b + c = 26 ------(3)

9a + 3b + c = 32 -------(4)

(2)->(3)

9a-3b-2-a-b = 26

8a-4b = 28

4(2a-b) = 28

2a-b = 7 ----(5)

(2)->(4)

9a+3b-2-a-b = 32

8a+2b = 34

2(4a+b) = 34

4a+b = 17 ----(6)

(5)+(6)

6a = 24

a = 4

sub a=4 into(6)

4(4)+b = 17

b = 1

sub a=4,b=1 into (2)

c = -2-4-1

c = -7

Answer:

E. None of the above answers is correct

Step-by-step explanation:

Analysis of variance (ANOVA) "is used to analyze the differences among group means in a sample".

The sum of squares "is the sum of the square of variation, where variation is defined as the spread between each individual value and the grand mean"

If we assume that we have [tex]5[/tex] groups and on each group from [tex]j=1,\dots,20[/tex] we have [tex]20[/tex] individuals on each group we can define the following formulas of variation:  

[tex]SS_{total}=\sum_{j=1}^p \sum_{i=1}^{n_j} (x_{ij}-\bar x)^2 [/tex]

[tex]SS_{between}=SS_{model}=\sum_{j=1}^p n_j (\bar x_{j}-\bar x)^2 [/tex]

[tex]SS_{within}=SS_{error}=\sum_{j=1}^p \sum_{i=1}^{n_j} (x_{ij}-\bar x_j)^2 [/tex]

And we have this property

[tex]SST=SS_{between}+SS_{within}[/tex]

The degrees of freedom for the numerator on this case is given by [tex]df_{num}=df_{within}=k-1=5-1=4[/tex] where k =5 represent the number of groups.

The degrees of freedom for the denominator on this case is given by [tex]df_{den}=df_{between}=N-K=5*20-5=95[/tex].

And the total degrees of freedom would be [tex]df=N-1=5*20 -1 =99[/tex]

On this case the correct answer would be 4 for the numerator and 95 for the denominator.

E. None of the above answers is correct

Final answer:

It would take roughly 22.22 hours to fill an 80,000 L swimming pool with a garden hose at a rate of 60 L/min. However, if diverting a moderate size river flowing at 5000 m³/s, it would fill the pool in approximately 0.016 seconds.

Explanation:

To estimate the time it would take to fill a private swimming pool with a capacity of 80,000 L using a garden hose delivering 60 L/min, we simply divide the total volume of the pool by the flow rate of the hose. For this calculation:

Time (min) = Total Volume (L) / Flow Rate (L/min)

Time = 80,000 L / 60 L/min = 1333.33 min

To convert minutes to hours, we divide by 60:

Time = 1333.33 min / 60 = 22.22 hours

For part (b), if you could divert a moderate size river, flowing at 5000 m³/s, into the pool, we need to convert this flow rate into liters per second (L/s) for consistency:

Flow Rate (L/s) = 5000 m³/s * 1000 L/m³

Flow Rate = 5000000 L/s

Now we can calculate the time it would take to fill the pool with this flow rate:

Time = 80,000 L / 5000000 L/s

Time = 0.016 seconds

Answer:

$12.50

Step-by-step explanation:

so Juan got his sweater at a 25% discount. So we woukd find 25% of 10 and then add it to $10

Answer:

Step-by-step explanation:

Juan only paid $10 for his new Sweater. He got a 25% discount

Let the original price of the sweater be $x. If he gets s 35% discount, it means that the price which she paid was lower than the original price.

Discount of 25% on the original price = 25/100 × x = 0.25x

The amount of money that Juan paid is the original price minus the discount of 25%. It becomes

x - 0.25x = 0.75x

Amount paid = $10. Therefore

0.75x = 10

x = 10/0.75 = $13.33

Answer:

(0,1) and (13,2)

Step-by-step explanation:

We are given that parametric equations

[tex]x=2t^3+3t^2-12t[/tex]

[tex]y=2t^3+3t^2+1[/tex]

a.We have to find the points where tangent line is horizontal.

Differentiate x and y w.r.t.time

[tex]\frac{dx}{dt}=6t^2+6t-12[/tex]

[tex]\frac{dy}{dt}=6t^2+6t[/tex]

[tex]\frac{dy}{dx}=\frac{\frac{dy}{dt}}{\frac{dx}{dt}}[/tex]

Substitute the values

[tex]\frac{dy}{dx}=\frac{6t^2+6t}{6t^2+6t-12}[/tex]

We know that when tangent line is horizontal then

[tex]\frac{dy}{dx}=0[/tex]

[tex]\frac{6t^2+6t}{6t^2+6t-12}=0[/tex]

[tex]6t^2+6t=0[/tex]

[tex]t^2+t=0[/tex]

[tex]t(t+1)=0[/tex]

[tex]t=0, t+1=0[/tex]

[tex]t+1=0\implies t=-1[/tex]

Substitute the t=0 then we get

[tex]x=2(0)^3+3(0)^2-12(0)=0[/tex]

[tex]y=2(0)^3+3(0)^2+1=1[/tex]

Substitute t=-1

[tex]x=2(-1)^3+3(-1)^2-12(-1)=-2+3+12=13[/tex]

[tex]y=2(-1)^3+3(-1)^2+1=-2+3+1=2[/tex]

The points  (0,1) and (13,2) where tangent line is horizontal .

To find the points where the tangent line is horizontal, we need to find the values of t that make the derivative of y with respect to x equal to 0. The points where the tangent line is horizontal are (0,1) and (20,0).

To find the points where the tangent line is horizontal, we need to find the values of t that make the derivative of y with respect to x equal to 0. Let's start by finding the derivatives of x and y with respect to t:

[d/dt(x)]=(6t^2)+(6t)-12

[d/dt(y)]=(6t^2)+(6t)

To find the values of t that make [d/dt(y)] equal to 0, we set (6t^2)+(6t)=0. By factoring out a 6t, we get t(t+1)=0. So t=0 or t=-1. We can substitute these values of t back into the parametric equations to find the corresponding points (x,y):

Therefore, the points (x,y) where the tangent line is horizontal are (0,1) and (20,0).

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Answer:

At least  one of the events A and B occurs:

(a) 0.5

(b) 0.44

All of the events A, B, C occur:

(a) 0.024

(b) 0

Step-by-step explanation:

Given:

P(A) = 0.2, P(B) = 0.3, P(C) = 0.4

At least  one of the events A and B occurs:

(a) If A and B are mutually exclusive events, then their intersection is 0.

Probability of at least one of them occurring means either of the two occurs or the union of the two events. Therefore,

[tex]P(A\ or\ B)=P(A)+P(B)-P(A\cap B)\\P(A\ or\ B)=0.2+0.3-0=0.5[/tex]

(b) If A and B are independent events, then their intersection is equal to the product of their individual probabilities. Therefore,

[tex]P(A\ or\ B)=P(A)+P(B)-P(A\cap B)\\P(A\ or\ B)=P(A)+P(B)+P(A)P(B)\\P(A\ or\ B)=0.2+0.3-(0.2)(0.3)=0.5-0.06=0.44[/tex]

All of the events A, B, C occur together:

(a) All of the events occurring together means the intersection of all the events.

If A, B, and C are independent events, then their intersection is equal to the product of their individual probabilities. Therefore,

[tex]P(A\cap B\cap C)=P(A)\cdot P(B)\cdot P(C)\\P(A\cap B\cap C)=0.2\times 0.3\times 0.4=0.024[/tex]

(b) If A, B, and C are mutually exclusive events means events A, B, and C can't happen at the same time. Therefore, their intersection is 0.

[tex]P(A\cap B\cap\ C)=0[/tex]

Probability that at least one of the events A and B occurs:

(a) When A and B are mutually exclusive: 0.5 (b) When A and B are independent: 0.44

Probability that all of the events A, B, and C occur:

(a) When A, B, and C are independent: 0.024 (b) When A, B, and C are mutually exclusive: 0

To solve these probability questions, let's understand the given information and the rules of probability related to mutually exclusive and independent events.

Let P(A) = 0.2, P(B) = 0.3, and P(C) = 0.4.

1. Finding the probability that at least one of the events A and B occurs:

(a) When A and B are mutually exclusive:

Mutually exclusive events mean that A and B cannot occur at the same time. Therefore, the probability that at least one of them occurs is given by:

P(A OR B) = P(A) + P(B)

So, P(A OR B) = 0.2 + 0.3 = 0.5

(b) When A and B are independent:

Independent events mean that the occurrence of one event does not affect the occurrence of the other. The probability that at least one of them occurs is given by:

P(A OR B) = P(A) + P(B) - P(A AND B)

For independent events, P(A AND B) is calculated as: P(A AND B) = P(A) × P(B)

So, P(A AND B) = 0.2 × 0.3 = 0.06

Therefore, P(A OR B) = 0.2 + 0.3 - 0.06 = 0.44

2. Finding the probability that all of the events A, B, and C occur:

(a) When A, B, and C are independent:

For independent events, the probability that all of them occur is given by:

P(A AND B AND C) = P(A) × P(B) × P(C)

So, P(A AND B AND C) = 0.2 × 0.3 × 0.4 = 0.024

(b) When A, B, and C are mutually exclusive:

If events are mutually exclusive, it means they cannot all occur together. Therefore, the probability that all of them occur is:

P(A AND B AND C) = 0

Answer:

x=11

Step-by-step explanation:

(a) False. The sum will not be around 1, give or take 1.   (b) False. The probability that the sum will be in the range 0 to 2 is not about 68%.

(a).

Expected sum = (99/100 x 0) + (1/100 x  1)

= 1/100

= 0.01

Therefore, the expected value of the sum is 0.01, which is much closer to 0 than 1. While it is possible to observe a sum of 1 or close to 1 in a particular set of draws, it is not likely to be the average or typical outcome.

(b) False. The probability that the sum will be in the range 0 to 2 is not about 68%.

To determine the probability, to consider the possible outcomes that result in a sum between 0 and 2.

The possible outcomes are:

Therefore, the total probability of the sum being in the range 0 to 2 is approximately:

[tex]0.366 + 0.369 + 0.185 = 0.92,[/tex]

which is far greater than 68%.

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Answer:

0.706

Step-by-step explanation:  

For uniformity, let's assuming none of the people selected is born on 29th of February. Therefore, the total possible birthday (sample space) for anybody selected is 365 days.  

Probability of having at least two people having or not having the same birthday sum up to 1. It is easier to calculate the probability of people not having the same birthday.  

The probability of at least two people having the same birthday = 1 - The probability of at least two people not having the same birthday  

Pr (First Person selected is born in a day in a year) = [tex]\frac{365}{365}[/tex]  

The next person selected is limited to 364 possible days

Pr (Second Person selected is born in a day in year) = [tex]\frac{364}{365}[/tex]  

The next person selected is limited to 363 possible days

Pr (Third Person selected is born in a day in year) = [tex]\frac{363}{365}[/tex]

The next person selected is limited to 362 possible days

Pr (Fourth Person selected is born in a day in year) = [tex]\frac{362}{365}[/tex]

The next person selected is limited to 361 possible days

Pr (Fifth Person selected is born in a day in year) = [tex]\frac{361}{365}[/tex]  

The next person selected is limited to 360 possible days

Pr (Sixth Person selected is born in a day in year) = [tex]\frac{360}{365}[/tex]

The next person selected is limited to 359 possible days

Pr (Seventh Person selected is born in a day in year) = [tex]\frac{359}{365}[/tex]  

Looking at the pattern, the pattern continues by descending by 1 day from 365. The last person selected will have 336 possible days (365 – 29 days ) the other people before have used up 29 potential days.  

Pr (Last Person selected is born in a day in year) = [tex]\frac{359}{365}[/tex]  

The probability of selecting at least two people that will not have the same birthday, is the product of their 30 individual birthday probability.

[tex]\frac{365}{365} * \frac{364}{365} * \frac{363}{365} * \frac{362}{365} * \frac{361}{365} * \frac{360}{365} * \frac{359}{365} ... \frac{337}{365} * \frac{336}{365} = [/tex]  

This is a huge a hug e calculation to simplify. For simplicity the numerator and the denominator will be calculated separately.

The denominator is product of 365 in 30 times.  

The denominator = 365³⁰

To simplify the numerator, the factorials method is used. Using factorials method, 365! = 365 × 364 × 363 × 362 × 361 × 360 × 359 × 358 ... × 3 × 2 × 1. But we only need the product of the integers from 365 to 336, so we’ll divide the unwanted numbers by dividing 365! by 335!  

The numerator = [tex]\frac{365!}{335!}[/tex]

Therefore,

                       [tex]\frac{365!}{335! * 365^{30}} = 0.294[/tex]

The probability that no one selected in the group has the same birthday is 0.294. The probability that at least two people will have the same birthday is the complement of the probability that no one in the group has the same birthday.

                                       1 - 0.294 = 0.706

The probability that at least two of them will have the same birthday = 0.706

The correct answer is approximately 0.7064.

To solve this problem, it is easier to calculate the probability that no one shares a birthday and then subtract this from 1 to find the probability that at least two people share a birthday.

Let's denote the probability that no two people share a birthday as P(no shared birthday). There are 365 days in a year, so the first person can have any birthday.

The second person then has 364 out of 365 days to have a different birthday, the third person has 363 out of 365 days, and so on, until the thirtieth person has 336 out of 365 days to avoid sharing a birthday with anyone else.

Thus, the probability that no one shares a birthday is:

[tex]\[ P(\text{no shared birthday}) = \frac{365}{365} \times \frac{364}{365} \times \frac{363}{365} \times \ldots \times \frac{336}{365} \][/tex]

We can calculate this product to find P(no shared birthday). Then, to find the probability that at least two people share a birthday, we subtract this from 1:

[tex]\[ P(\text{at least one shared birthday}) = 1 - P(\text{no shared birthday}) \][/tex]

Calculating the product for P(no shared birthday) and subtracting from 1 gives us the probability that at least two people in the group of thirty will have the same birthday.

When rounded to four decimal places, this probability is approximately 0.7064.

The critical t values are reject the null hypothesis and shut down the process.

The correct option is (A).

To find the critical t values for a one-tailed t-test with a significance level of [tex]\( \alpha = 0.10 \)[/tex], we need to look up the t-distribution table or use statistical software.

Since we have a sample size of 17, the degrees of freedom ( df ) for the t-test will be [tex]\( n - 1 = 17 - 1 = 16 \).[/tex]

For a one-tailed t-test with a significance level of [tex]\( \alpha = 0.10 \)[/tex] and 16 degrees of freedom, we find the critical t value.

From the t-distribution table or using statistical software, the critical t value for [tex]\( \alpha = 0.10 \) and \( df = 16 \)[/tex] is approximately 1.337.

So, the critical t values are approximately [tex]\( \pm 1.337 \).[/tex]

Now, we compare the calculated t value for the sample mean to these critical values. If the calculated t value falls beyond these critical values, we reject the null hypothesis.

Since the problem does not provide the calculated t value, we cannot determine whether to reject the null hypothesis or not.

However, based on the information given, we can see that the mean weight of the USB flash drives in the last sample is 31.9 grams, which is heavier than the expected mean weight of 30 grams. If the calculated t value corresponds to a significantly larger value than the critical t value, we may reject the null hypothesis and conclude that the mean weight is significantly different from 30 grams, potentially leading to shutting down the process for adjustment.

Therefore, the correct answer would be:

A. reject the null hypothesis and shut down the process.

Since |4.35| > 1.746, we reject the null hypothesis and conclude that the mean weight of the USB flash drives is significantly different from 30 grams. Therefore, the correct answer is: A. reject the null hypothesis and shut down the process.

To find the critical t-values for a significance level of [tex]\( \alpha = 0.10 \)[/tex] and a sample size of n = 17, we can use a t-distribution table or a statistical software.

For a two-tailed test at a significance level of [tex]\( \alpha = 0.10 \)[/tex] and degrees of freedom df = n - 1 = 17 - 1 = 16, we need to find the critical t-values that correspond to the upper and lower tails of the t-distribution.

Using a t-distribution table or a statistical software, the critical t-values for a significance level of [tex]\( \alpha = 0.10 \)[/tex] and 16 degrees of freedom are approximately [tex]\( t_{\alpha/2} = \pm 1.746 \).[/tex]

So, the critical t-values are approximately[tex]\( \pm 1.746 \).[/tex]

Now, let's compare the calculated t-value with the critical t-values:

The calculated t-value is given by:

[tex]\[ t = \frac{\bar{x} - \mu}{\frac{s}{\sqrt{n}}} \][/tex]

Where:

- [tex]\( \bar{x} \)[/tex] is the sample mean (31.9 grams)

- [tex]\( \mu \)[/tex] is the population mean (30 grams)

- s is the sample standard deviation (1.8 grams)

- n is the sample size (17)

Substitute the given values:

[tex]\[ t = \frac{31.9 - 30}{\frac{1.8}{\sqrt{17}}} \]\[ t \approx \frac{1.9}{\frac{1.8}{4.123}} \]\[ t \approx \frac{1.9}{0.437} \]\[ t \approx 4.35 \][/tex]

Since |4.35| > 1.746, we reject the null hypothesis and conclude that the mean weight of the USB flash drives is significantly different from 30 grams. Therefore, the correct answer is:

A. reject the null hypothesis and shut down the process.

Answer:

Step-by-step explanation:

The given quadratic equation is

2x^2+3x-8 = 0

To find the roots of the equation. We will apply the general formula for quadratic equations

x = -b ± √b^2 - 4ac]/2a

from the equation,

a = 2

b = 3

c = -8

It becomes

x = [- 3 ± √3^2 - 4(2 × -8)]/2×2

x = - 3 ± √9 - 4(- 16)]/2×2

x = [- 3 ± √9 + 64]/2×2

x = [- 3 ± √73]/4

x = [- 3 ± 8.544]/4

x = (-3 + 8.544) /4 or x = (-3 - 8.544) / 4

x = 5.544/4 or - 11.544/4

x = 1.386 or x = - 2.886

The positive solution is 1.39 rounded up to the nearest hundredth

Answer:

its a. 1.39

Step-by-step explanation:

Answer:

45/100 = 0.45

Step-by-step explanation:

Divide 9 by 20.

9/20 = 0.45

Now write 36/100 as a decimal.

36/100 = 0.36

Write 45/100 as a decimal: 0.45

Answer: 45/100 = 0.45

Answer: 99% confidence interval would be [tex](1346.37,1553.63)[/tex]

Step-by-step explanation:

Since we have given that

Sample size = 30

Sample mean = $1450

Standard deviation = $220

We need to find the 99% confidence interval.

So, z = 2.58

So, confidence interval would be

[tex]\bar{x}\pm z\dfrac{\sigma}{\sqrt{n}}\\\\=1450\pm 2.58\times \dfrac{220}{\sqrt{30}}\\\\=1450\pm 103.63\\\\=(1450-103.63,1450+103.63)\\\\=(1346.37,1553.63)[/tex]

Hence, 99% confidence interval would be [tex](1346.37,1553.63)[/tex]

64

Step-by-step explanation:

We will divide the volume of the larger cube with that if the smaller cube. However, we’ll first have to convert them to the same SI units;

12 inches  = 1 foot

Therefore the volume of the larger cube;

12 * 12 * 12 = 1728 inches cubed

The volume of the smaller cube;

3 * 3 * 3 = 27 inches cubed

Divide the two;

1728/27

= 64

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Answer:

0.191 is the probability that a group of 12 randomly selected applicants would have a mean SAT score that is greater than 525 but below the current admission standard of 584.

Step-by-step explanation:

We are given the following information in the question:

Mean, μ = 500

Standard Deviation, σ = 100

n = 12

We are given that the distribution of SAT score is a bell shaped distribution that is a normal distribution.

Formula:

[tex]z_{score} = \displaystyle\frac{x-\mu}{\sigma}[/tex]

P(greater than 525 but 584)

Standard error due to sampling =

[tex]\displaystyle\frac{\sigma}{\sqrt{n}} = \frac{100}{\sqrt{12}}[/tex]

[tex]P(525 < x < 584) = P(\displaystyle\frac{525 - 500}{\frac{100}{\sqrt{12}}} < z < \displaystyle\frac{584-500}{\frac{100}{\sqrt{12}}}) = P(0.866 < z < 2.909)\\\\= P(z \leq 2.909) - P(z < 0.866)\\= 0.998 - 0.807 = 0.191 = 19.1\%[/tex]

[tex]P(525 < x < 584) = 19.1\%[/tex]

0.191 is the probability that a group of 12 randomly selected applicants would have a mean SAT score that is greater than 525 but below the current admission standard of 584.