Description
Solve the system https://tcan4424-oakcliff-ccl.gradpoint.com/Resour...
A.infinite solutions | |
B. | (0, 3) |
C. | no solution |
D. | (3, -1 |
Which ordered pair is a solution to the system of inequalities https://tcan4424-oakcliff-ccl.gradpoint.com/Resour...
A,(3, 1) | |
B. | (–3, 1) |
C. | (0, 4) |
D. | (2, –1) |
Graph the system of inequalities https://tcan4424-oakcliff-ccl.gradpoint.com/Resour...
Which quadrant does the solution lie in?
a.Quadrant 4 | |
b. | Quadrant 1 |
c. | Quadrant 3 |
d. | Quadrant 2 |
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Explanation & Answer
1. A. infinite solutions
2. B. (-3,1)
3. a. Quadrant 4
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#Lab 9#274-Wilcox (Fall 2019)#Name:#Student ID:rm(list=ls())source('Rallfun-v33.txt')#PART 1#Suppose you want to test whether or not boys like the T.V. show Rick and Morty better than girls. You ask 10 boys and 10 girls to rate the T.V. show on a scale from 1 to 7, where 7 is highly enjoyable and 1 is not enjoyable.#For the boys, you observe the values:# 5 7 6 3 1 1 2 4 5 6#For the girls, you observe the values:# 1 3 7 7 6 4 3 5 7 4#1.1) Are the groups independent?#1.2) Examine the means and SDs for each of the groups#1.3) Look at a histogram for both groups#1.4) Use the appropriate t-test to test the null hypothesis that mean score for boys=girls #1.5) Do you reject or fail to reject the null?#PART 2#Suppose you want to test the effectiveness of a new drug, Cholmed, that helps treat high cholesterol in adults. In your study, you have 16 people who have been diagnosed with high cholesterol. To 8 of them, you give regular doses of Cholmed over one month. 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Comparing Independent Groups#--------------------------------------------------------------------------------- #Previously we learned the function t.test(), #which we used to conduct one-sample t-tests.#We can extend our knowledge of this function #for using it to compare 2 independent groups.#All we need to do is to add another variable to the function#Two ways to perform an Indepedent Sample t-test in R:# t.test(y~g)#where y is a vector of scores of the data and#g is a grouping variable# t.test(x, y)#where x and y represent scores from group 1 and #group 2, respectively#Which to use depends on how your DATA are STRUCTURED.#In Chapter 9, you learned two types of two-sample t tests: #1) Student's two-sample t-test (assumes variance is equal) #2) Welch's test (assumes variance is NOT equal)#The function t.test() can run either; #you change the parameter "var.equal"#to change which test you use#(remember: Student's t assumes equal variances).#To run two-sample t-test:#^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^## Student's t-test: t.test(x, y, var.equal=TRUE) OR # t.test(y~g, var.equal=TRUE)# Welch's test: t.test(x,y, var.equal=FALSE) OR # t.test(y~g, var.equal=FALSE)#^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^##We're going to create some data we can practice on using#the rnorm() function we learned before.#Let's assume that I measured 20 young people and #25 old people on some measure #(could be anything...perhaps IQ)#I'll simulate what their data might look like. young=rnorm(n=20, mean=0, sd=1)old=rnorm(n=25, mean=0.5, sd=1)#Our interest here is find out if the mean for this #variable is different between young and old people. mean(young); mean(old)#Because our data is structured such that each group #has it's own variable, we'll use the t.test function #that allows for that.#Similarly, we need to decide if we're going to use the#student's t-test or the welch's t-test.#NOTE: we simulated the data so that the variance would be #equal, so we'll presume that the student t-test is fine.#Remember we are testing:#H0: mu1 = mu2#HA: mu1 != mu2#We also have degrees_of_freedom=N1+N2-2t.test(old, young, var.equal=TRUE)#We then compare the p-value to our alpha level#A) If pval < alpha, then Reject the Null Hypothesis#B) If pval > alpha, then Fail to Reject the Null Hypothesis#Fail to reject!#OK...now, we're going to rearrange our data so that #it looks more like it will in real life when you collect it:yourdata=as.data.frame(matrix(, ncol=2, nrow=45))colnames(yourdata) = c("outcome", "group")yourdata[1:20, "outcome"]=youngyourdata[1:20, "group"]=1yourdata[21:45, "outcome"]=oldyourdata[21:45, "group"]=2yourdata#We can then run the more usual specification which is:t.test(yourdata$outcome ~ yourdata$group, var.equal=TRUE)#For the rest of the lab, we will use the t.test() #specification where each group has it's own variable.#??????????????????????????????????????????????????????????????##Thought Question 1: Given all that we've just discussed, what does#it mean to reject the null hypothesis using our t.test? #??????????????????????????????????????????????????????????????##---------------------------------------------------------------------------------# 2. 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After that, you ask them how much they like pizza.#Before the study, you observe the values:# 7 7 3 1 6 5 4 3 3 4 6 7#After the study, you observe the values:# 2 1 4 4 1 1 2 1 6 4 5 4 #3.1) Are the groups independent? Examine the means and SDs for each of the groups#3.2) Use the appropriate t-test to test the null hypothesis that mean score for before=after. Do you reject or fail to reject the null?Cannot use external packagesPlease see lecture notes below provided by professor to do lab homework above, and to follow their packages and formulas please#Lab 9-Contents (Lecture Notes)#1. Comparing Independent Groups#2. The T-test: The influence of differences in the Means#3. The T-test: The influence of differences in the Variance #4. The T-test: The influence of differences in Skewness#5. The T-test with Trimmed Means: Yuen's T#6. Comparing Dependent Groups: The Paired T-test#Goal: In this lab we will look at comparing #independent and dependent groups in R#---------------------------------------------------------------------------------# 1. Comparing Independent Groups#--------------------------------------------------------------------------------- #Previously we learned the function t.test(), #which we used to conduct one-sample t-tests.#We can extend our knowledge of this function #for using it to compare 2 independent groups.#All we need to do is to add another variable to the function#Two ways to perform an Indepedent Sample t-test in R:# t.test(y~g)#where y is a vector of scores of the data and#g is a grouping variable# t.test(x, y)#where x and y represent scores from group 1 and #group 2, respectively#Which to use depends on how your DATA are STRUCTURED.#In Chapter 9, you learned two types of two-sample t tests: #1) Student's two-sample t-test (assumes variance is equal) #2) Welch's test (assumes variance is NOT equal)#The function t.test() can run either; #you change the parameter "var.equal"#to change which test you use#(remember: Student's t assumes equal variances).#To run two-sample t-test:#^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^## Student's t-test: t.test(x, y, var.equal=TRUE) OR # t.test(y~g, var.equal=TRUE)# Welch's test: t.test(x,y, var.equal=FALSE) OR # t.test(y~g, var.equal=FALSE)#^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^##We're going to create some data we can practice on using#the rnorm() function we learned before.#Let's assume that I measured 20 young people and #25 old people on some measure #(could be anything...perhaps IQ)#I'll simulate what their data might look like. young=rnorm(n=20, mean=0, sd=1)old=rnorm(n=25, mean=0.5, sd=1)#Our interest here is find out if the mean for this #variable is different between young and old people. mean(young); mean(old)#Because our data is structured such that each group #has it's own variable, we'll use the t.test function #that allows for that.#Similarly, we need to decide if we're going to use the#student's t-test or the welch's t-test.#NOTE: we simulated the data so that the variance would be #equal, so we'll presume that the student t-test is fine.#Remember we are testing:#H0: mu1 = mu2#HA: mu1 != mu2#We also have degrees_of_freedom=N1+N2-2t.test(old, young, var.equal=TRUE)#We then compare the p-value to our alpha level#A) If pval < alpha, then Reject the Null Hypothesis#B) If pval > alpha, then Fail to Reject the Null Hypothesis#Fail to reject!#OK...now, we're going to rearrange our data so that #it looks more like it will in real life when you collect it:yourdata=as.data.frame(matrix(, ncol=2, nrow=45))colnames(yourdata) = c("outcome", "group")yourdata[1:20, "outcome"]=youngyourdata[1:20, "group"]=1yourdata[21:45, "outcome"]=oldyourdata[21:45, "group"]=2yourdata#We can then run the more usual specification which is:t.test(yourdata$outcome ~ yourdata$group, var.equal=TRUE)#For the rest of the lab, we will use the t.test() #specification where each group has it's own variable.#??????????????????????????????????????????????????????????????##Thought Question 1: Given all that we've just discussed, what does#it mean to reject the null hypothesis using our t.test? #??????????????????????????????????????????????????????????????##---------------------------------------------------------------------------------# 2. The T-test: The influence of differences in the Means#--------------------------------------------------------------------------------- #Let's first load the table object lab9.txt lab9=read.table ('lab9.txt', header=T) #Choose lab9.txthead(lab9)#Check if the table is properly stored#Your table should look like the one below:# x y1a y1b y2a y2b y3a y3b#1 -3.16919102 -1.16919102 -0.669191 -6.575259 0.6328316 3.7191954 -0.2191954#2 -6.35526894 -4.35526894 -3.855269 -16.133493 -0.4291944 3.1886523 0.3113477#3 -1.91975197 0.08024803 0.580248 -2.826942 1.0493113 3.7193226 -0.2193226#4 2.58377901 4.58377901 5.083779 10.683651 2.5504883 0.4866459 3.0133541#5 -0.88984272 1.11015728 1.610157 0.262786 1.3926144 -9.3365268 12.8365268#6 0.02129019 2.02129019 2.521290 2.996185 1.6963254 2.3916263 1.1083737#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##Exercise 2-1: # A) What are the means and SDs for the variables x, y1a, and y1b?# B) Look histograms of the three variables. # C) Based on what you saw in #A), # what are the differences between these 3 variables?# D) Run the appropriate t-test to test the following 2 null hypotheses:#H0: mean x = mean y1a#AND#H0: mean x = mean y1b # E) Do you reject or fail to reject the null hypotheses tested above in #D)? #*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##A) mean(lab9$x); sd(lab9$x)mean(lab9$y1a); sd(lab9$y1a)mean(lab9$y1b); sd(lab9$y1b)#B) hist(lab9$x)hist(lab9$y1a)hist(lab9$y1b)#C) #D) t.test(lab9$x, lab9$y1a, var.equal=TRUE)t.test(lab9$x, lab9$y1b, var.equal=TRUE)#E) #We then compare the p-value to our alpha level#A) If pval < alpha, then Reject the Null Hypothesis#B) If pval > alpha, then Fail to Reject the Null Hypothesis#H0: mean x = mean y1a#p-value=... therefore ...#H0: mean x = mean y1b #p-value=... therefore ...#What conclusion can you make based on the results from #the two t-tests? In other words, how does the difference #in Means between two samples affect our t-test result #assuming other things (e.g., sample size, difference in variance, skewness) are held constant.#See Figure 9.3 in your book#Power of any method based on means is highly sensitive to#small changes in the tails of the distributions and that#situations where outliers tend to occur have the potential #of masking an important difference among the bulk of the #participants.#---------------------------------------------------------------------------------# 3. The T-test: The influence of differences in the Variance #--------------------------------------------------------------------------------- #*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##Exercise 3-1: # A) What are the means and SDs for the variables x, y2a, and y2b?# B) Look histograms of the three variables. # C) Based on what you saw in #A), what are the differences between these 3 variables?# D) Run the appropriate t-test to test the following 2 null hypotheses:#H0: mean x = mean y2a#AND#H0: mean x = mean y2b # E) Do you reject or fail to reject the null hypotheses tested above in #D)? #*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##A) mean(lab9$x); sd(lab9$x)mean(lab9$y2a); sd(lab9$y2a) mean(lab9$y2b); sd(lab9$y2b)#B) hist(lab9$x)hist(lab9$y2a) hist(lab9$y2b)#C) #??#D) #??#E) #We then compare the p-value to our alpha level#A) If pval < alpha, then Reject the Null Hypothesis#B) If pval > alpha, then Fail to Reject the Null Hypothesis#???#What conclusion can you make based on the results from the#two t-tests? In other words, how does the difference #in variance between two samples affect our t-test result #assuming other things (e.g., sample size, #difference in means, skewness) are held constant.#Problems with controlling the probability of a Type I error occur:#It can yield inaccurate confidence intervals when sampling #from normal distributions with unequal sample sizes #and unequal variances.#---------------------------------------------------------------------------------# 4. The T-test: The influence of differences in Skewness#--------------------------------------------------------------------------------- #*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##Exercise 4-1: # A) What are the means and SDs for the variables x, y3a, and y3b?# B) Look histograms of the three variables. # C) Based on what you saw in #A), what are the differences between these 3 variables?# D) Run the appropriate t-test to test the following 2 null hypotheses:#H0: mean x = mean y3a#AND#H0: mean x = mean y3b # E) Do you reject or fail to reject the null hypotheses tested above in #D)? #*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##A) mean(lab9$x); sd(lab9$x)mean(lab9$y3a); sd(lab9$y3a) mean(lab9$y3b); sd(lab9$y3b)#B) hist(lab9$x)hist(lab9$y3a) #Left Skewhist(lab9$y3b) #Right Skew#C) #Same Means (kinda), same variance, just different skew #D) t.test(lab9$x, lab9$y3a, var.equal=TRUE)t.test(lab9$x, lab9$y3b, var.equal=TRUE)#E) #We then compare the p-value to our alpha level#A) If pval < alpha, then Reject the Null Hypothesis#B) If pval > alpha, then Fail to Reject the Null Hypothesis#Fail to reject H0#Reject H0#Figure 9.2 in your book#When dealing with groups that differ in skewness, #again problems with controlling the probability of a Type I error occur,#and the combination of unequal variances and different amounts of skewness #makes matters worse.#---------------------------------------------------------------------------------# 5. The T-test with Trimmed Means: Yuen's T#--------------------------------------------------------------------------------- #As we saw above, skewness can have an influence on #our ability to detect statistical significance. #Using our univariate outlier detection method (MAD-Median),#we can see that both y3a and y3b have numerous outliers#NOTE: You must load the Rallfun-v33 source code to use the out() functionout(lab9$y3a) #5 outliersout(lab9$y3b) #5 outliers #Given that we have these outliers, we should consider using #a technique that compares the Trimmed Means#The Trimmed Means version of a t-test is called Yuen's Method#^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^## Yuen's Trimmed t-test: yuen(x, y, tr=0.2) #^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^##*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##Exercise 5-1: # A) Re-test the hypotheses from Exercise 4-1 using Yuen's# method (with 20% trimming)# B) How do the results comapre to what you concluded previously? #*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*#*##A) #HINT: find the p-value to make conclusionyuen(lab9$x, lab9$y3a, tr=0.2)yuen(lab9$x, lab9$y3b, tr=0.2)#B) #???#Given what we've just seen, how might skewness #affect the results we get?#---------------------------------------------------------------------------------# 6. Comparing Dependent Groups: The Paired T-test#--------------------------------------------------------------------------------- #We just learned the various ways to conduct a t-test#for independent groups (ie. different people in each group). #We used Student's t-test, Welch's, and Yuen's. #Now we are going to learn about what to do when #our groups are dependent (ie. same people in each group). #Often the dependent groups we see are based on time, #such that people are measured at baseline (group1) #and we want to see how much they've changed at followup (group2). #Here is an example:#We are interested in measuring the weight of college freshmen before and after the first year #(to test whether or not there is any truth to the "freshman 15"?). We tested 16 freshmen on the #first day of school, and tested them again after finals week of the spring semester. The data #is recorded in a table in frosh.txt.frosh=read.table('frosh.txt', header=T)frosh#It is not valid to use a two-sample t-test to compare #the weight gain becuase the data are dependent (on the #same person)#Instead we will use the paired t-test.#The formula for calculating a paired t-test in R is again t.test(). #However, we change one parameter:#^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^## Paired t-test: t.test(x, y, paired=TRUE) #^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^##Let's run a PAIRED t-test for our data from the freshmen:t.test(frosh$Weight_before,frosh$Weight_after, paired=TRUE) #What would have happend if we ignored the fact that #this was a PAIRED or REPEATED Measure Design?#Let's find out by running the normal independent samples T-Testt.test(frosh$Weight_before,frosh$Weight_after) #Remember: This is WRONG
RES-845 Module 4 SPSS Data Interpretation
Details:A related samples t-test compares the mean values of two related samples. In this assignment, you will review the ...
RES-845 Module 4 SPSS Data Interpretation
Details:A related samples t-test compares the mean values of two related samples. In this assignment, you will review the SPSS output for a related samples t-test and use it to answer questions about the means of the two related samples.General Requirements:Use the following information to ensure successful completion of the assignment:Review "SPSS Access Instructions" for information on how to access SPSS for this assignment.Download “SPSS Data Set Legend" for use with this assignment.Download “Module 4 SPSS Output" for use with this assignment.Directions:Review the SPSS output file that reports the results of the related samples t-test to compare the number of U.S. states where each brand was sold in 2008 with the number of U.S. states where those same brands were sold in 2012. For each brand, there is one value for the number of states in 2008 and another value for the number of states in 2012, making this a repeated measure. Answer the following questions based on your observations of the SPSS output file:What was the mean number of U.S. states in which all of the beer brands were sold in 2008?What was the mean number of U.S. states in which all of the beer brands were sold in 2012?Was there a significant difference in the number of states in which these beer brands were sold in 2008 versus 2012? Report the results of the t-test as follows: t(df value) = ___, and p-value.Please complete the assignment as required and please use the appropriate references , if applicable, and cite in APA 6th edition format. Please see the attached documentation for completion of assignment.
MATH 107 University of Maryland College Algebra Math Final Exam
I've attached the test, answer sheet, and the first two questions of the test seperately. First two questions got cut off ...
MATH 107 University of Maryland College Algebra Math Final Exam
I've attached the test, answer sheet, and the first two questions of the test seperately. First two questions got cut off for some reason. If you need anything else please let me know.
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