`fitlm`

will be able to do this for you quite nicely. You use `fitlm`

to **train** a linear regression model, so you provide it the predictors as well as the responses. Once you do this, you can then use `predict`

to predict the new responses based on new predictors that you put in.

The basic way for you to call this is:

```
lmModel = fitlm(X, y, 'linear', 'RobustOpts', 'on');
```

`X`

is a data matrix where each **column** is a predictor and each **row** is an observation. Therefore, you would have to **transpose** your matrix before running this function. Basically, you would do `P(1:3,:).'`

as you only want the first three rows (now columns) of your data. `y`

would be your output values for each observation and this is a column vector that has the same number of rows as your observations. Regarding your comment about using the "last" column as the response vector, you don't have to do this at all. You specify your response vector in a completely separate input variable, which is `y`

. As such, your `a1`

would serve here, while your predictors and observations would be stored in `X`

. You can totally place your response vector as a column in your matrix; you would just have to subset it accordingly.

As such, `y`

would be your `a1`

variable, and **make sure** it's a column vector, and so you can do this `a1(:)`

to be sure. The `linear`

flag specifies linear regression, but that is the default flag anyway. `RobustOpts`

is recommended so that you can perform robust linear regression. For your case, you would have to call `fitlm`

this way:

```
lmModel = fitlm(P(1:3,:).', a1(:), 'linear', 'RobustOpts', 'on');
```

Now to **predict** new responses, you would do:

```
ypred = predict(lmModel, Xnew);
```

`Xnew`

would be your new observations that follow the same style as `X`

. You have to have the **same number of columns** as `X`

, but you can have as many rows as you want. The output `ypred`

will give you the predicted response for each observation of `X`

that you have. As an example, let's use a dataset that is built into MATLAB, split up the data into a training and test data set, fit a model with the training set, then use the test dataset and see what the predicted responses are. Let's split up the data so that it's a 75% / 25% ratio. We will use the `carsmall`

dataset which contains 100 observations for various cars and have descriptors such as `Weight`

, `Displacement`

, `Model`

... typically used to describe cars. We will use `Weight, Cylinders`

and `Acceleration`

as the predictor variables, and let's try and predict the miles per gallon `MPG`

as our outcome. Once I do this, let's calculate the difference between the predicted values and the true values and compare between them. As such:

```
load carsmall; %// Load in dataset
%// Build predictors and outcome
X = [Weight Cylinders Acceleration];
y = MPG;
%// Set seed for reproducibility
rng(1234);
%// Generate training and test data sets
%// Randomly select 75 observations for the training
%// dataset. First generate the indices to select the data
indTrain = randperm(100, 75);
%// The above may generate an error if you have anything below R2012a
%// As such, try this if the above doesn't work
%//indTrain = randPerm(100);
%//indTrain = indTrain(1:75);
%// Get those indices that haven't been selected as the test dataset
indTest = 1 : 100;
indTest(indTrain) = [];
%// Now build our test and training data
trainX = X(indTrain, :);
trainy = y(indTrain);
testX = X(indTest, :);
testy = y(indTest);
%// Fit linear model
lmModel = fitlm(trainX, trainy, 'linear', 'RobustOpts', 'on');
%// Now predict
ypred = predict(lmModel, testX);
%// Show differences between predicted and true test output
diffPredict = abs(ypred - testy);
```

This is what happens when you echo out what the linear model looks like:

```
lmModel =
Linear regression model (robust fit):
y ~ 1 + x1 + x2 + x3
Estimated Coefficients:
Estimate SE tStat pValue
__________ _________ _______ __________
(Intercept) 52.495 3.7425 14.027 1.7839e-21
x1 -0.0047557 0.0011591 -4.1031 0.00011432
x2 -2.0326 0.60512 -3.359 0.0013029
x3 -0.26011 0.1666 -1.5613 0.12323
Number of observations: 70, Error degrees of freedom: 66
Root Mean Squared Error: 3.64
R-squared: 0.788, Adjusted R-Squared 0.778
F-statistic vs. constant model: 81.7, p-value = 3.54e-22
```

This all comes from statistical analysis, but for a novice, what matters are the `p-values`

for each of our predictors. The smaller the p-value, the more suitable this predictor is for your model. You can see that the first two predictors: `Weight`

and `Cylinders`

are a good representation on determining the `MPG`

. `Acceleration`

... not so much. What this means is that this variable is not a meaningful predictor to use, so you should probably use something else. In fact, if you were to remove this predictor and retrain your model, you would most likely see that the predicted values would closely match those where the `Acceleration`

was included.

This is a truly bastardized version of interpreting `p-values`

and so I defer you to an actual regression models or statistics course for more details.

This is what we have predicted the values to be, given our test set and beside it what the true values are:

```
>> [ypred testy]
ans =
17.0324 18.0000
12.9886 15.0000
13.1869 14.0000
14.1885 NaN
16.9899 14.0000
29.1824 24.0000
23.0753 18.0000
28.6148 28.0000
28.2572 25.0000
29.0365 26.0000
20.5819 22.0000
18.3324 20.0000
20.4845 17.5000
22.3334 19.0000
12.2569 16.5000
13.9280 13.0000
14.7350 13.0000
26.6757 27.0000
30.9686 36.0000
30.4179 31.0000
29.7588 36.0000
30.6631 38.0000
28.2995 26.0000
22.9933 22.0000
28.0751 32.0000
```

The fourth actual output value from the test data set is `NaN`

, which denotes that the value is missing. However, when we run our the observation corresponding to this output value into our linear model, it predicts a value anyway which is to be expected. You have other observations to help train the model that when using this observation to find a prediction, it would naturally draw from those other observations.

When we compute the difference between these two, we get:

```
diffPredict =
0.9676
2.0114
0.8131
NaN
2.9899
5.1824
5.0753
0.6148
3.2572
3.0365
1.4181
1.6676
2.9845
3.3334
4.2431
0.9280
1.7350
0.3243
5.0314
0.5821
6.2412
7.3369
2.2995
0.9933
3.9249
```

As you can see, there are some instances where the prediction was quite close, and others where the prediction was far from the truth.... it's the crux of any prediction algorithm really. You'll have to play around with what predictors you want, as well as playing with the options with your training. Have a look at the `fitlm`

documentation for more details on what you can play around with.

# Edit - July 30th, 2014

As you don't have `fitlm`

, you can easily use `LinearModel.fit`

. You would call it with the same inputs like `fitlm`

. As such:

```
lmModel = LinearModel.fit(trainX, trainy, 'linear', 'RobustOpts', 'on');
```

This should give you exactly the same results. `predict`

should exist pre-R2014a, so that should be available to you.

Good luck!