Plot 95% Confidence Interval R
- Excel Regression Plot 95 Confidence Interval
- Plot 95% Confidence Interval R
- Find Confidence Interval R
- Plot Confidence Intervals In Excel
- How to calculate confidence interval in R Science. A confidence interval for the population mean gives an indication of how accurately the sample mean estimates the population mean. A 95% confidence interval is defined as an interval calculated in such a way that if a large number of samples were drawn from a population and the.
- This gives the confidence intervals for each of the three tests. For example, in the first experiment the 95% confidence interval is between -0.97 and -0.03 assuming that the random variables are normally distributed, and the samples are independent.
The 'base package' in R does not have a command to calculate confidence intervals for RRs, ORs. However, there are supplemental packages that can be loaded into R to add additional analytical tools, including confidence intervals for RR and OR. These tools are in the ' epitools ' package.
You must first install the package on your computer (just once), but each time you want to use it in an active R session, you need to load it.
Installing the epitools Package into R
Type the following to install the epitools package (this only needs to be done once):
The R package boot allows a user to easily generate bootstrap samples of virtually any statistic that they can calculate in R. From these samples, you can generate estimates of bias, bootstrap confidence intervals, or plots of your bootstrap replicates. Here we show how to calculate confidence intervals for sample means, and plot these intervals along with the raw data.
>install.packages('epitools')
You should see the following message as a response in red:
Installing package into 'C:/Users/healeym/Documents/R/win-library/3.3' (as 'lib' is unspecified) trying URL 'https://cran.rstudio.com/bin/windows/contrib/3.3/epitools_0.5-7.zip' Content type'application/zip' length 228486 bytes (223 KB) downloaded 223 KB
package 'epitools' successfully unpacked and MD5 sums checked The downloaded binary packages are in C:UsersyourusernameAppDataLocalTempRtmpsLajiUdownloaded_packages
Loading the epitools Package When You Want to Use It
You only have to install the epitools package once, but you have to call it up each time you use it.
>library(epitools)
Warning message: package 'epitools' was built under R version 3.4.2
RRs and ORs from R
Situation #1: Starting with Counts from a Contingency Table:
If you are given the counts in a contingency table, i.e., you do not have the raw data set, you can re-create the table in R and then compute the risk ratio and its 95% confidence limits using the riskratio.wald() function in Epitools.
No CVD | CVD | Total | |
No HTN | 1017 | 165 | 1182 |
HTN | 2260 | 992 | 3252 |
Total | 3277 | 1157 | 4434 |
This is where the orientation of the contingency table is critical, i.e., with the unexposed (reference) group in the first row and the subjects without the outcome in the first column.
We create the contingency table in R using the matrix function and entering the data for the 1st column, then 2nd column. Note that we only enter the observed counts for each of the exposure-disease categories; we do not enter the totals in the margins. The solution in R is as follows:
Risk Ratio and Confidence Interval in R
R Code:
# The 1stline below creates the contingency table; the 2nd line prints the table so you can check the orientation
>RRtable<-matrix(c(1017,2260,165,992),nrow = 2, ncol = 2)
>RRtable
[,1] [,2]
[1,] 1017 165
[2,] 2260 992
# The next line asks R to compute the RR and 95% confidence interval
>riskratio.wald(RRtable)
$data
Outcome
Predictor Disease1 Disease2 Total
Exposed1 1017 165 1182
Exposed2 2260 992 3252
Total 3277 1157 4434
$measure
risk ratio with 95% C.I.
Predictor estimate lower upper
Exposed1 1.000000 NA
Exposed22.185217 1.879441 2.540742
$p.value
two-sided
Predictor midp.exact fisher.exact chi.square
Exposed1 NA
Exposed2 0 7.357611e-31 1.35953e-28zz
$correction [1] FALSE
attr(,'method') [1] 'Unconditional MLE & normal approximation (Wald) CI'
The risk ratio and 95% confidence interval are listed in the output under $measure.
Odds Ratio and 95% Confidence Interval in R
Case-control studies use an odds ratio as the measure of association, but this procedure is very similar to the analysis above for RR.
>ORtable<-matrix(c(1017,2260,165,992),nrow = 2, ncol = 2)
>ORtable
[,1] [,2]
[1,] 1017 165
[2,] 2260 992
>oddsratio.wald(ORtable)
$data
Outcome
Predictor Disease1 Disease2 Total
Exposed1 1017 165 1182
Exposed2 2260 992 3252
Total 3277 1157 4434
$measure
odds ratio with 95% C.I.
Predictor estimate lower upper
Exposed1 1.000000 NA
Exposed22.705455 2.258339 3.241093
$p.value two-sided
Predictor midp.exact fisher.exact chi.square
Exposed1 NA
Exposed2 0 7.357611e-31 1.35953e-28
$correction [1] FALSE
attr(,'method')
[1] 'Unconditional MLE & normal approximation (Wald) CI'
Situation #2: Starting with Counts from a Raw Data Set:
If you have a raw data set, computing risk ratios and odds ratios and their corresponding 95% confidence intervals is even easier, because the contingency table can be created using the table() command instead of the matrix function.
For example, if I have data from the Framingham Heart Study and I want to compute the risk ratio for the association between type 2 diabetes and risk of being hospitalized with a myocardial infarction, I first use the table() command.
> table(diabetes,hospmi)
hospmi
diabetes 0 1
0 2557 210
1 183 48
Then, to compute the risk ratio and confidence limits, I insert the table parameters into the riskratio.wald() function:
> riskratio.wald(table(diabetes,hospmi))
$data
hospmi
diabetes 0 1 Total
0 2557 210 2767
1 183 48 231
Total 2740 258 2998
$measure
risk ratio with 95% C.I.
diabetes estimate lower upper
0 1.00000 NA NA
1 2.73791 2.062282 3.63488
Using the same data, I can similarly compute an odds ratio and its confidence interval using the oddsratio.wald()function:
> oddsratio.wald(table(diabetes,hospmi))
$data
hospmi
diabetes 0 1 Total
0 2557 210 2767
1 183 48 231
Total 2740 258 2998
$measure
odds ratio with 95% C.I.
diabetes estimate lower upper
0 1.000000 NA NA
1 3.193755 2.256038 4.521233
Note that, since this is a cohort study, it makes sense to compute the risk ratio, but I also have the option of computing an odds ratio, although in a case-control study one can only calculate an odds ratio. Notice also that in the example above, the odds ratio was somewhat more extreme than the risk ratio.
Test Yourself
Problem #1
A clinical trial was conducted to compare a new blood pressure-lowering medication to a placebo. Patients were enrolled and randomized to receive either the new medication or a placebo. The data below were collected at the end of the 6 week study.
Excel Regression Plot 95 Confidence Interval
Treatment (n=100) | Placebo (n=100) | |
Systolic Blood Pressure, mean (sd) | 120.2 (15.4) | 131.4 (18.9) |
Hypertensive, % | 14% | 22% |
Side Effects, % | 6% | 8% |
Plot 95% Confidence Interval R
Generate a point estimate and 95% confidence interval for the risk ratio of side effects in patients assigned to the experimental group as compared to placebo. Use both the hand calculation method and the method using R to see if you get the same answers. Interpret the results in a sentence or two.
Link to Answer in a Word fileProblem #2
The table below summarizes parental characteristics for children of normal weight and children classified as overweight or obese. Perform a chi-square test by hand to determine if there is an association between the mother's BMI and the child's weight status. Compute the p-value and report your conclusion.
Characteristics | Child - Normal Weight (n=62) | Child - Overweight/Obese (n=38) | Total (n=100) |
Mean (SD) Age, years | 13.4 (2.6) | 11.1 (2.9) | 12.5 (2.7) |
% Male | 45% | 51% | 47% |
Mother's BMI | |||
Normal (BMI<25) | 40 (65%) | 16 (41%) | 56 (56%) |
Overweight (BMI 25-29.9) | 15 (24%) | 14 (38%) | 29 (29%) |
Obese (BMI > 30) | 7 (11%) | 8 (21%) | 15 (15%) |
Father's BMI | |||
Normal (BMI<25) | 34 (55%) | 16 (41%) | 50 (50%) |
Overweight (BMI 25-29.9) | 20 (32%) | 14 (38%) | 34 (34%) |
Obese (BMI > 30) | 8 (13%) | 8 (21%) | 16 (16%) |
Mean (SD) Systolic BP | 123 (15) | 139 (12) | 129 (14) |
Mean (SD) Total Cholesterol | 186 (25) | 211 (28) | 196 (26) |
Find Confidence Interval R
Plot Confidence Intervals In Excel
return to top previous page next page