3(n+8)=13
Gizmos Solving Algebraic Equations 2

Answer:

[tex] ME= \frac{69.397-60.128}{2}= 4.6345 \approx 4.635[/tex]

And the best answer on this case would be:

b) m = 4.635

Step-by-step explanation:

Let X the random variable of interest and we know that the confidence interval for the population mean [tex]\mu[/tex] is given by this formula:

[tex] \bar X \pm t_{\alpha/2} \frac{s}{\sqrt{n}} [/tex]

The confidence level on this case is 0.9 and the significance [tex]\alpha=1-0.9=0.1[/tex]

The confidence interval calculated on this case is [tex]60.128 \leq \mu \leq 69.397[/tex]

The margin of error for this confidence interval is given by:

[tex]ME =t_{\alpha/2} \frac{s}{\sqrt{n}} [/tex]

Since the confidence interval is symmetrical we can estimate the margin of error with the following formula:

[tex] ME = \frac{Upper -Lower}{2}[/tex]

Where Upper and Lower represent the bounds for the confidence interval calculated and replacing we got:

[tex] ME= \frac{69.397-60.128}{2}= 4.6345 \approx 4.635[/tex]

And the best answer on this case would be:

b) m = 4.635

Answer:

24 324

Step-by-step explanation:

21334 fda  adf

Answer: 24, 324

Step-by-step explanation:

Find the perimiter of both sides

Answer:

14 sq cm

Step-by-step explanation:

7 × 4 = 28

28 ÷ 2 = 14

brainliest?

Answer:

it equals 1

Step-by-step explanation:

(5)(2)+2x−7=5

Step 1: Simplify both sides of the equation.

(5)(2)+2x−7=5

10+2x+−7=5

(2x)+(10+−7)=5(Combine Like Terms)

2x+3=5

2x+3=5

Step 2: Subtract 3 from both sides.

2x+3−3=5−3

2x=2

Step 3: Divide both sides by 2.

2x

2

=

2

2

x=1

Answer:

12.

Step-by-step explanation:

Given that,

Number of while balls are 3

Number of green balls are 4

Number of red balls are 5

We need to find the total number of outcomes. We know the total number of outcomes in is number of choices.

In this case, total number of outcomes are the sum of all color balls i.e. 3 + 4 + 5 = 12 balls.

Hence, the total number of outcomes are 12.

Final answer:

The total number of outcomes when one ball is drawn at random from a bag containing 3 white, 4 green, and 5 red balls is 12.

Explanation:

A bag contains 3 white balls, 4 green balls, and 5 red balls. The total number of possible outcomes when a ball is drawn at random is simply the sum of all the balls in the bag. Since each ball can be selected in one distinct way, we calculate the total number of outcomes by adding the number of white balls, the number of green balls, and the number of red balls.

So, the total number of outcomes is:

3 (white) + 4 (green) + 5 (red) = 12 (total outcomes)

Therefore, there are 12 different possible outcomes when one ball is drawn at random from this bag.

Answer:

The standard error (SE) is 0.1847.

The t-statistic for this test is 2.490.

Step-by-step explanation:

We are given that the sample has a mean of [tex]\bar X[/tex] = 101.09 and a standard deviation of s = 0.4887 .

Also, the 7 sample values are also given.

Let [tex]\mu[/tex] = population mean.

So, Null Hypothesis, [tex]H_0[/tex] : [tex]\mu[/tex] = 100.63  

Alternate Hypothesis, [tex]H_1[/tex] : [tex]\mu[/tex] > 100.63  

The test statistics that would be used here One-sample t test statistics as we don't know about population standard deviation;

                         T.S. =  [tex]\frac{\bar X-\mu}{\frac{s}{\sqrt{n} } }[/tex]  ~ [tex]t_n_-_1[/tex]

where, [tex]\bar X[/tex] = sample mean = 101.09

            s = sample standard deviation = 0.4887

            n = sample values = 7

The Standard Error (SE) is given by =  [tex]\frac{s}{\sqrt{n} }[/tex]  =  [tex]\frac{0.4887}{\sqrt{7} }[/tex] = 0.1847

So, test statistics  =  [tex]\frac{101.09-100.63}{\frac{0.4887}{\sqrt{7} } }[/tex]  ~ [tex]t_6[/tex]

                                =  2.490

The value of t test statistics is 2.490.

Answer:

the interval would get bigger.

Step-by-step explanation:

if you wanted to be more confident in the interval you're giving, you would make more of the answers fit under the umbrella you're hypothetically creating.

Answer:

The value of t test statistics is 4.518.

Step-by-step explanation:

We are given that director of a radio broadcasting company wants to determine whether the mean length of commercials on his station is equal to 24 seconds.

He samples 200 commercials, and finds that the average length of these commercials is 26.3 seconds, with a standard deviation of 7.2 seconds.

Let [tex]\mu[/tex] = mean length of commercials on his station.

So, Null Hypothesis, [tex]H_0[/tex] : [tex]\mu[/tex] = 24 seconds     {means that the mean length of commercials on his station is equal to 24 seconds}

Alternate Hypothesis, [tex]H_A[/tex] : [tex]\mu\neq[/tex] 24 seconds     {means that the mean length of commercials on his station is different from 24 seconds}

The test statistics that would be used here One-sample t test statistics as we don't know about the population standard deviation;

                        T.S. =  [tex]\frac{\bar X-\mu}{\frac{s}{\sqrt{n} } }[/tex]  ~ [tex]t_n_-_1[/tex]

where, [tex]\bar X[/tex] = sample average length of these commercials = 26.3 seconds

            s = sample standard deviation = 7.2 seconds

            n = sample of commercials = 200

So, test statistics  =  [tex]\frac{26.3-24}{\frac{7.2}{\sqrt{200} } }[/tex]  ~ [tex]t_1_9_9[/tex]  

                               =  4.518

The value of t test statistics is 4.518.

cones

cylinders

spheres

Step-by-step explanation:

The question was worded incorrectly and instead of giving the options it gave you the answers

Answer:

a) [tex]P(E) = \frac{6}{8}[/tex]

b) [tex]P(F|E) = \frac{5}{7}[/tex]

c) [tex]P(E \cap F) = \frac{15}{28}[/tex]

Step-by-step explanation:

We use the conditional probability formula to solve this question. It is

[tex]P(B|A) = \frac{P(A \cap B)}{P(A)}[/tex]

In which

P(B|A) is the probability of event B happening, given that A happened.

[tex]P(A \cap B)[/tex] is the probability of both A and B happening.

P(A) is the probability of A happening.

We have that:

8 vehicles, of which 6 are vans.

a.) Let E denote the event that the first vehicle assigned is a van. What is P(E) ?

8 vehicles, of which 6 are vans.

So

[tex]P(E) = \frac{6}{8}[/tex]

b.) Let F denote the probability that the second vehicle assigned is a van. What is P(F|E)?

P(F|E) is the probability that the second vehicle assigned is a van, given that the first one was.

In this case, there are 7 vehicles, of which 5 are vans. So

[tex]P(F|E) = \frac{5}{7}[/tex]

c.) Use the results of parts(a) and (b) to calculate P(E and F)

[tex]P(F|E) = \frac{P(E \cap F)}{P(E)}[/tex]

[tex]P(E \cap F) = P(F|E)P(E)[/tex]

[tex]P(E \cap F) = \frac{6}{8}\frac{5}{7}[/tex]

[tex]P(E \cap F) = \frac{15}{28}[/tex]

The probability of the first vehicle assigned being a van is 3/4, and the conditional probability of the second vehicle being a van given the first was a van is 5/7. The probability that both vehicles assigned are vans is 15/28.

The subject of this question is probability, a topic in Mathematics. We are asked to find the probability of a certain event occurring under certain conditions.

https://brainly.com/question/22962752

#SPJ3

Answer:

Barney 145 3 Days 310 Miles

Mary   250 5 Days 600 Miles

A)  3 D + 310 M = 145

B) 5 D + 600 M = 250

Multiplying A) by -5/3

A) -5 D - 516.6666M = -241.66666666

B) 5D + 600M = 250

Adding A) and B)

83.3333 M = 8.3333333333

M = .10 per mile

3 D = 114

Daily Rate = 38 dollars per day

Step-by-step explanation:

Answer:

The test statistic t = 1.126 <  1.703 of '27' degrees of freedom at 0.05 level of significance.

null hypothesis(H₀ ) is accepted

There is evidence that the average breaking strength is  7.000.

Step-by-step explanation:

Step 1:-

Given random sample size (n) =28 <30

small sample size n= 28

The sample mean (x⁻) = 7.142

sample standard deviation (S) =0.672

Step 2:-

Null hypothesis :- there is evidence that the average breaking strength is  7.000.

H₀ : μ =7

Alternative hypothesis:-there is evidence that the average breaking strength is  7.000.

H₁ : μ ≠7

The test statistic [tex]t = \frac{x^{-} -mean}{\frac{S}{\sqrt{n} } }[/tex]

Substitute all values and simplification ,

[tex]t = \frac{7.142 -7}{\frac{0.672}{\sqrt{28} } } = \frac{0.142 }{0.1269}[/tex]

t = 1.126

Calculated value is t = 1.126

The degrees of freedom γ = n-1 = 28-1 =27

The tabulated value t= 1.703 at degrees of freedom at 0.05 level of significance.

since  calculated t < tabulated value 't' value of 27 degrees of freedom at 0.05 level of significance.

null hypothesis(H₀ ) is accepted

There is evidence that the average breaking strength is  7.000.

Answer:

1. There are 648 total combinations that can be chosen.

2. After she choses two possiblilities the total number changes to 108 total posibilities to chose from

Step-by-step explanation:

possibility: 1/2 x 1/3 x 1/2 x 1/6 x 1/9 = 648

then you remove the first two because she chose those ones

1/2 x 1/6 x 1/9 = 108 possibilities left

Answer:

Step-by-step explanation:

1.       C

2.        C

3.         B

Answer:

-4

Step-by-step explanation:

Each term is 4 less than the term before it, so the common difference is -4.

Answer:

B. -4 on edge !!

Step-by-step explanation:

Got it right :)

Answer:

3

Step-by-step explanation:

Answer:

The correct option is;

Callie multiplied incorrectly

Step-by-step explanation:

Here we have 0.42 × 4.73 = 1.9866 then

1.9866 + 29.4 + 168 = 199.3866

Therefore, from the question, we had 0.42 × 4.73 = 1.26 which is incorrect, meaning that Callie multiplied incorrectly

Apparently, Callie multiplied as follows;

0.42 × 3 = 1.26 but what was in the question was

0.42 × 4.73 which is equal to 1.9866.

Answer:

Callie multiplied incorrectly

Step-by-step explanation:

all the credit goes to guy above me

The question is a college-level mathematics problem focusing on statistics related to normal distribution, particularly the calculation of probabilities, defining a random variable, and understanding hypothesis testing and p-values.

The student's question pertains to the concept of normal distribution and statistics as applied to biological data. Specifically, it involves analysis using the mean and standard deviation of a dataset, and proper understanding of hypothesis testing and p-values in scientific research.

Understanding the Random Variable X

The random variable X, in this context, represents the duration of criminal trials. The question requires defining X and calculating related probabilities using the normal distribution properties. A probability statement and sketching of the graph would aid in visual understanding of the probabilities in question.

In statistical hypothesis testing, a p-value less than the level of significance (e.g., 0.01) typically leads to rejection of the null hypothesis, indicating evidence supporting the alternative hypothesis. The data on fruit flies' fecundity and genetic traits provided is an example of such an analysis.

Final answer:

The probability that a randomly selected golf ball from the bag is not a type A ball is 11/16, as we calculate this by dividing the number of non-type A balls (11) by the total number of balls (16).

Explanation:

The probability that the golf ball selected at random is not a type A ball can be found by first determining the total number of balls in the golf bag and then subtracting the number of type A balls to obtain the number of non-type A balls. The total number of balls is 5 type A balls + 8 type B balls + 3 type C balls = 16 balls. The number of non-type A balls is 8 type B balls + 3 type C balls = 11 balls.

To find the probability that the selected ball is not a type A ball, we divide the number of non-type A balls by the total number of balls, which gives us a probability of 11/16.

Final answer:

The probability that a randomly selected golf ball from the bag is not a type A ball is 0.6875 or 68.75%.

Explanation:

To find the probability that the golf ball selected at random is not a type A ball, we need to determine the total number of non-type A balls in the golf bag and divide it by the total number of balls in the bag. The golf bag contains 5 type A balls, 8 type B balls, and 3 type C balls, so the total number of balls in the bag is 5 + 8 + 3 = 16. There are 8 + 3 = 11 non-type A balls (type B and type C).

The probability of selecting a non-type A ball is then given by the number of non-type A balls divided by the total number of balls:

Probability = Number of non-type A balls / Total number of balls

We calculate it as:

Probability = 11 / 16 = 0.6875

Thus, the probability that the selected golf ball is not a type A ball is 0.6875 or 68.75%.

To calculate milk needed for a different number of pancakes and determine the amount of butter for a varied pancake quantity.

To calculate the amount of milk needed for 4 pancakes that Simon is making:

Divide the amount of milk needed for 8 pancakes (250ml) by 2 since 4 is half of 8. 250ml ÷ 2 = 125ml.

To determine the amount of butter for the 12 pancakes that Craig is making:

Since the recipe calls for 5g of butter for 8 pancakes, we can calculate the amount needed for 12 pancakes by setting up a proportion: (5g/8 pancakes) = (x/12 pancakes). Solving for x gives x = 7.5g.

Answer:

  7 is located to the right of -2

Step-by-step explanation:

Larger numbers are to the right on a number line, so the statement that 7 is larger than -2 means ...

  7 is located to the right of -2

Answer: b. finding all studies published on a topic, calculating the effect size for each of those studies, and averaging the effect sizes together to find the average size of the effect across all studies.

Step-by-step explanation:

The null hypothesis will be rejected if the test statistic is: greater than -2.33

The null hypothesis will be rejected if the test statistic falls within the critical region, which is determined by the significance level (0.01 in this case).

To determine the test statistic, calculate the z-score for the sample proportion and compare it to the critical value.

The formula to calculate the z-score for the sample proportion is:

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

Where:

[tex]\hat{p}[/tex] is the sample proportion (230/1189 = 0.193)

p is the population proportion (0.22)

n is the sample size (1189)

Calculating the z-score:

z = (0.193 - 0.22) / [tex]\sqrt[/tex](0.22 * (1 - 0.22) / 1189)

z = -2.25

To determine if the null hypothesis is rejected or not, compare the absolute value of the z-score to the critical value for a one-tailed test at a 0.01 significance level.

The critical value for a one-tailed test at a 0.01 significance level is approximately -2.33.

If the absolute value of the calculated z-score is greater than 2.33, we reject the null hypothesis.

Since absolute value of the calculated z-score is not greater than 2.33, null hypothesis is not rejected.

Answer:

Part (A)

Part (B)

Part (C)

Explanation:

0. Write the monthly cost and​ price-demand equations correctly:

Cost:

      [tex]C(x)=72,000+70x[/tex]

Price-demand:

      [tex]p(x)=300-\dfrac{x}{20}[/tex]

Domain:

        [tex]0\leq x\leq 6000[/tex]

1. Part (A) Find the maximum revenue

Revenue = price × quantity

Revenue = R(x)

           [tex]R(x)=\bigg(300-\dfrac{x}{20}\bigg)\cdot x[/tex]

Simplify

      [tex]R(x)=300x-\dfrac{x^2}{20}[/tex]

A local maximum (or minimum) is reached when the first derivative, R'(x), equals 0.

         [tex]R'(x)=300-\dfrac{x}{10}[/tex]

Solve for R'(x)=0

      [tex]300-\dfrac{x}{10}=0[/tex]

       [tex]3000-x=0\\\\x=3000[/tex]

Is this a maximum or a minimum? Since the coefficient of the quadratic term of R(x) is negative, it is a parabola that opens downward, meaning that its vertex is a maximum.

Hence, the maximum revenue is obtained when the production level is 3,000 units.

And it is calculated by subsituting x = 3,000 in the equation for R(x):

Hence, the maximum revenue is $450,000

2. Part ​(B) Find the maximum​ profit, the production level that will realize the maximum​ profit, and the price the company should charge for each television set.

i) Profit(x) = Revenue(x) - Cost(x)

       [tex]Profit(x)=300x-\dfrac{x^2}{20}-\big(72,000+70x\big)[/tex]

       [tex]Profit(x)=230x-\dfrac{x^2}{20}-72,000\\\\\\Profit(x)=-\dfrac{x^2}{20}+230x-72,000[/tex]

ii) Find the first derivative and equal to 0 (it will be a maximum because the quadratic function is a parabola that opens downward)

Thus, the production level that will realize the maximum profit is 2,300 units.

iii) Find the maximum profit.

You must substitute x = 2,300 into the equation for the profit:

Hence, the maximum profit is $192,500

iv) Find the price the company should charge for each television set:

Use the price-demand equation:

Therefore, the company should charge a price os $185 for every television set.

3. ​Part (C) If the government decides to tax the company ​$4 for each set it​ produces, how many sets should the company manufacture each month to maximize its​ profit? What is the maximum​ profit? What should the company charge for each​ set?

i) Now you must subtract the $4  tax for each television set, this is 4x from the profit equation.

The new profit equation will be:

ii) Find the first derivative and make it equal to 0:

Then, the new maximum profit is reached when the production level is 2,260 units.

iii) Find the maximum profit by substituting x = 2,260 into the profit equation:

Hence, the maximum profit, if the government decides to tax the company $4 for each set it produces would be $183,800

iv) Find the price the company should charge for each set.

Substitute the number of units, 2,260, into the equation for the price:

That is, the company should charge $187 per television set.

Answer:

  y = -2

Step-by-step explanation:

The equation of a horizontal line is ...

  y = constant

In order to make it go through a point with a y-coordinate of -2, the value of the constant must be -2.

Your line is y = -2.

Answer:

15/56

Step-by-step explanation:

Total = 8

3/8 × 5/7

15/56

Final answer:

None of the provided expressions have a greatest common factor of 3xy² with 42xy⁴ because they do not contain the necessary factors of 3, x, and y².

Explanation:

The student is asking for expressions that have a greatest common factor (GCF) of 3xy² with 42xy⁴. To find expressions with a GCF of 3xy², we need to look for expressions that include multiples of 3xy² in their factorization.

Looking at the provided expressions:

Therefore, none of the provided expressions have a GCF of 3xy² with 42xy⁴.

Answer:

The calculated value z = 1.3145 < 2.326 at  0.02 level of significance

The null hypothesis is accepted

Hence An automobile manufacturer claims that its car has a 28.0 miles/gallon (MPG) rating.

Step-by-step explanation:

Step(i):-

An automobile manufacturer claims that its car has a 28.0 miles/gallon (MPG) rating.

The mean of the Population 'μ' = 28.0miles/gallon

Given data after testing 270 cars, they found a mean MPG of 27.8. Assume the variance is known to be 6.25.

The sample size 'n' = 270

Mean of the sample 'x⁻' = 27.8

Given Population variance 'σ² = 6.25

The standard deviation of Population 'σ' = √6.25 = 2.5

Step(ii):-

Null hypothesis :H₀: 'μ' = 28.

Alternative hypothesis :H₁: 'μ' ≠28.

The test statistic

[tex]Z = \frac{x^{-}-mean }{\frac{S.D}{\sqrt{n} } }[/tex]

[tex]Z = \frac{27.8-28 }{\frac{2.5}{\sqrt{270} } } = \frac{-0.2}{0.15214}[/tex]

Z = -1.3145

|Z| = |-1.3145|= 1.3145

Step(iii):-

The tabulated value  of z-score at 0.02 level of significance = 2.326

The calculated value z = 1.3145 < 2.326 at a t 0.02 level of significance

The null hypothesis is accepted

Hence An automobile manufacturer claims that its car has a 28.0 miles/gallon (MPG) rating.

Answer:-18-9=-17

Step-by-step explanation:

Answer:

-27

Step-by-step explanation:

Nine less than negative eighteen

[tex] - 18 - 9 = - 27[/tex]

Final answer:

The question involves Mathematics and requires understanding of statistics and normal distribution to find z-scores for designing helmets to fit a specific range of male head breadths, accommodating all except the smallest and largest 4.3%.

Explanation:

The subject of this question is Mathematics, specifically focusing on statistics and the concept of normal distribution. Engineers designing helmets need to consider the breadths of male heads, which are normally distributed with a given mean and standard deviation. The design requirements stipulate that the helmets should fit all men except for those in the extremities of the distribution (smallest 4.3% and largest 4.3%).

To address such a problem, one would typically use the z-score to identify the cutoff points on a standard normal distribution that correspond to these percentages. The z-score represents the number of standard deviations a data point is from the mean. Therefore, the engineers must calculate the z-scores that correspond to the smallest and largest 4.3% of the distribution to determine the range of head breadths the helmets must accommodate.

Using the median concept, it is found that the second quartile is of 86.

The median of the data-set separates the bottom half from the upper half, that is, it is the 50th percentile. The median is also called the second quartile, as [tex]\frac{2}{4} \times 100 = 50[/tex].

In this problem, there are 22 scores, which is an even number, hence the median is the mean of the 11th and the 12th scores.

From the stem-and-leaf plot, we have that:

Then:

(85 + 87)/2 = 86

The second quartile is of 86.

You can learn more about the median concept at https://brainly.com/question/25215461

To find the quartiles of a dataset, arrange the data in ascending order, determine the median (Q2), split the data into a lower half and an upper half (excluding the median if the number of data points is odd), and find Q1 and Q3 as the medians of these subgroups.

To find the quartiles for a set of test scores, first arrange the data from lowest to highest and then divide the dataset into four equal parts. The second quartile (Q2), also known as the median, separates the data into two halves. In this case, because we have 22 data points, the median will be the average of the 11th and 12th data points.

To calculate the first quartile (Q1), we find the median of the lower half of the data, which consists of the 10 scores below the overall median. Since we have an even number of data points in the lower half, Q1 will be the average of the 5th and 6th smallest scores.

Similarly, the third quartile (Q3) is the median of the upper half, consisting of the 10 scores above the overall median. Q3 will be the average of the 5th and 6th highest scores within this upper half.