Forecasting-2-2---TV-Regression.html

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---



class: center, middle, inverse
# Forecasting Time Series
## Time-varying Regression: Forecasting

.futnote[Eli Holmes, UW SAFS]

.citation[eeholmes@uw.edu]

---



Forecasting is easy in R once you have a fitted model.  

Let's say for the anchovy, we fit the model

`$$C_t = \alpha + \beta t + e_t$$`
where `\(t\)` starts at 0 (so 1964 is `\(t=0\)` ).  To predict, predict the catch in year t, we use

`$$C_t = \alpha + \beta t + e_t$$`
---

Model fit:


```r
model &lt;- lm(log.metric.tons ~ t, data=anchovy)
coef(model)
```

```
## (Intercept)           t 
##  8.41962028  0.05818942
```

For anchovy, the estimated `\(\alpha\)` (Intercept) is 8.4196203 and `\(\beta\)` is 0.0581894.  We want to use these estimates to forecast 1988 ( `\(t=24\)` ).

So the 1988 forecast is 8.4196203 + 0.0581894 `\(\times\)` 24 :


```r
coef(model)[1]+coef(model)[2]*24
```

```
## (Intercept) 
##    9.816166
```

log metric tons.

---

# The forecast package

The forecast package in R makes it easy to create forecasts with fitted models and to plot (some of) those forecasts.

For a TV Regression model, our `forecast()` call looks like


```r
library(forecast)
fr &lt;- forecast(model, newdata = data.frame(t=24:28))
```

---

The dark grey bands are the 80% prediction intervals and the light grey are the 95% prediction intervals.


```r
plot(fr)
```

&lt;img src="Forecasting-2-2---TV-Regression_files/figure-html/plot.TVreg.forecast-1.png" style="display: block; margin: auto;" /&gt;

---

Sardine forecasts from a higher order polynomial can similarly be made.  Let's fit a 4-th order polynomial.


`$$C_t = \alpha + \beta_1 t + \beta_2 t^2 + \beta_3 t^3 + \beta_4 t^4 + e_t$$`

To forecast with this model, we fit the model to estimate the `\(\beta\)`'s and then replace `\(t\)` with `\(24\)`:

`$$C_{1988} = \alpha + \beta_1 24 + \beta_2 24^2 + \beta_3 24^3 + \beta_4 24^4 + e_t$$`

---

This is how to do that in R:


```r
model &lt;- lm(log.metric.tons ~ t + I(t^2) + I(t^3) + I(t^4), data=anchovy)
fr &lt;- forecast(model, newdata = data.frame(t=24:28))
fr
```

```
##   Point Forecast    Lo 80    Hi 80    Lo 95    Hi 95
## 1       10.18017 9.856576 10.50377 9.670058 10.69028
## 2       10.30288 9.849849 10.75591 9.588723 11.01704
## 3       10.41391 9.770926 11.05689 9.400315 11.42750
## 4       10.50839 9.609866 11.40691 9.091963 11.92482
## 5       10.58101 9.354533 11.80748 8.647599 12.51442
```

---

Unfortunately, forecast does not recognize that there is only one predictor `\(t\)` and we cannot use forecast's plot function.

If you do this in R, it throws an error.

```r
try(plot(fr))
```

```
## Error in plotlmforecast(x, PI = PI, shaded = shaded, shadecols = shadecols,  : 
##   Forecast plot for regression models only available for a single predictor
```

```
Error in plotlmforecast(x, PI = PI, shaded = shaded, shadecols = shadecols, : Forecast plot for regression models only available for a single predictor
```

---



I created a function that you can use to plot time-varying regressions with polynomial `\(t\)`.  You will use this function in the lab.


```r
plotforecasttv(model, ylims=c(8,17))
```

&lt;img src="Forecasting-2-2---TV-Regression_files/figure-html/plot.TVreg.forecast2-1.png" style="display: block; margin: auto;" /&gt;

---

A feature of a time-varying regression with many polynomials is that it fits the data well, but the forecast quickly becomes uncertain due to uncertainty regarding the polynomial fit.  A simpler model can give forecasts that do not become rapidly uncertain.

The flip-side is that the simpler model may not capture the short-term trends very well and may suffer from autocorrelated residuals.




```r
model &lt;- lm(log.metric.tons ~ t + I(t^2), data=sardine)
```

---


```r
plotforecasttv(model, ylims=c(8,17))
```

&lt;img src="Forecasting-2-2---TV-Regression_files/figure-html/plot.TVreg.lm1-1.png" style="display: block; margin: auto;" /&gt;

---

# Summary

* Time-varying regression is a simple approach to forecasting that allows a non-linear trend.
* The uncertainty in your forecast is determined by how much error there is between the fit an the data.
* Fit must be balanced against prediction uncertainty.
* R allows you to quickly fit models and compute the prediction intervals.

Careful thought must be given to selecting the polynomial order.

* Standard methods are available in R for order selection
* Using different orders for different data sets has prediction consequences
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