# How to plot a response variable with 3 factors in R?

I have the following table in R:

``````  ExperimentID clients connections msgSize     Mean Deviation     Error
1             4      50          50      10 73.19379 21.313889 0.2263254
2             5      50          10      10 73.25170 21.457139 0.2265276
3             6      50         100      10 73.20642 21.396485 0.2261432
4             7      50          50    1999 53.75247 11.863616 0.1695395
5             8      50          10    1999 53.88464 12.778998 0.2234775
6             9      50         100    1999 53.99422 11.947930 0.2085102
7            10      10          50    1999 49.74034  9.296995 0.3855425
8            11      10          10    1999 49.77624  8.639379 0.3566724
9            12      10         100    1999 50.30912 10.800443 0.4442306
10           13      10          50      10 68.80108 19.674006 0.5892552
11           14      10          10      10 69.41143 19.671618 0.5845524
12           15      10         100      10 69.09130 19.821473 0.5894541
13           16     100          10    1999 56.32045 16.370877 0.1940681
14           17     100          50    1999 55.93405 14.007772 0.2272496
``````

Now, I want to plot the column "Mean" as a function of the factors: clients, connections and msgSize. I think that a reasonable way to do this would be to prepare two histograms, one for msgSize = 10, and another for msgSize = 1999. In each of these two histograms, I can have the number of clients on the x-axis and the mean on y-axis. For each tick on the x-axis (ie. for a particular value of clients), I can have 3 bars (each corresponding to the mean for 10, 50 or 100 connections). How can I achieve this in R?

P.S: I am a newbie to R, so a bit detailed answer would be helpful. If there is a better answer with ggplot, that is also fine.

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``````data = read.csv(file="home",sep=",")

df = data.frame(data)
df

ExperimentID clients connections msgSize     Mean Deviation     Error
1             4      50          50      10 73.19379 21.313889 0.2263254
2             5      50          10      10 73.25170 21.457139 0.2265276
3             6      50         100      10 73.20642 21.396485 0.2261432
4             7      50          50    1999 53.75247 11.863616 0.1695395
5             8      50          10    1999 53.88464 12.778998 0.2234775
6             9      50         100    1999 53.99422 11.947930 0.2085102
7            10      10          50    1999 49.74034  9.296995 0.3855425
8            11      10          10    1999 49.77624  8.639379 0.3566724
9            12      10         100    1999 50.30912 10.800443 0.4442306
10           13      10          50      10 68.80108 19.674006 0.5892552
11           14      10          10      10 69.41143 19.671618 0.5845524
12           15      10         100      10 69.09130 19.821473 0.5894541
13           16     100          10    1999 56.32045 16.370877 0.1940681
14           17     100          50    1999 55.93405 14.007772 0.2272496

par(mfrow=c(1,2)) #plot two graphs (Message Size = 10 and Message Size = 1999) side by side.

msg_10 = subset(df, data_df\$msgSize == 10)
msg_10

ExperimentID clients connections msgSize     Mean Deviation     Error
1             4      50          50      10 73.19379  21.31389 0.2263254
2             5      50          10      10 73.25170  21.45714 0.2265276
3             6      50         100      10 73.20642  21.39648 0.2261432
10           13      10          50      10 68.80108  19.67401 0.5892552
11           14      10          10      10 69.41143  19.67162 0.5845524
12           15      10         100      10 69.09130  19.82147 0.5894541

plot(msg_10\$Mean ~ msg_10\$clients, col=as.factor(msg_10\$connections), pch=19,  xlab="Clients", ylab="Mean", xlim=c(0,60), ylim=c(68,74), main="Message Size = 10",cex.main=0.85)
legend("bottomright", legend=unique(msg_10\$connections), col=as.factor(msg_10\$connections),pch=19,title="connections")

msg_1999 = subset(df, data_df\$msgSize == 1999)
msg_1999

ExperimentID clients connections msgSize     Mean Deviation     Error
4             7      50          50    1999 53.75247 11.863616 0.1695395
5             8      50          10    1999 53.88464 12.778998 0.2234775
6             9      50         100    1999 53.99422 11.947930 0.2085102
7            10      10          50    1999 49.74034  9.296995 0.3855425
8            11      10          10    1999 49.77624  8.639379 0.3566724
9            12      10         100    1999 50.30912 10.800443 0.4442306
13           16     100          10    1999 56.32045 16.370877 0.1940681
14           17     100          50    1999 55.93405 14.007772 0.2272496

plot(msg_1999\$Mean ~ msg_1999\$clients, col=as.factor(msg_1999\$connections), pch=19, xlab="Clients", ylab="Mean", xlim=c(0,100), ylim=c(48,58), main="Message Size = 1999",cex.main=0.85)
legend("bottomright", legend=unique(msg_1999\$connections), col=as.factor(msg_1999\$connections),pch=19,title="connections")
``````

Here is the output:

Edit. I had overlooked the tag. So here is another option:

library (ggplot2)

``````#Message Size = 10
ggplot(data=msg_10,aes(clients,Mean)) + geom_point(data=msg_10,aes(color=as.factor(connections)),size=5) + theme_bw() + labs(title="Message Size = 10", color="Connections")

#Message Size = 1999
ggplot(data=msg_1999,aes(clients,Mean)) + geom_point(data=msg_1999,aes(color=as.factor(connections)),size=5) + theme_bw() + labs(title="Message Size = 1999", color="Connections")
``````

The second chart (Message Size = 1999) would look like this:

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