dates for term tests
DESCRIPTION
Dates for term tests. Friday, February 5 Friday, March 5 Friday, March 26. Let { x t | t T } be defined by the equation. The Moving Average Time series of order q, MA(q). where { u t | t T } denote a white noise time series with variance s 2. - PowerPoint PPT PresentationTRANSCRIPT
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Dates for term tests
1. Friday, February 5
2. Friday, March 5
3. Friday, March 26
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The Moving Average Time series of order q, MA(q)
where {ut|t T} denote a white noise time series with variance 2.
Let {xt|t T} be defined by the equation.
1 1 2 2 t t t t q t qx u u u u
Then {xt|t T} is called a Moving Average time series of order q. (denoted by MA(q))
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qi
qih
hq
ihii
0
if0
2
The autocorrelation function for an MA(q) time series
The autocovariance function for an MA(q) time series
qi
qihh
q
ii
hq
ihii
0
if0 0
2
0
The mean value for an MA(q) time series
tE x
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The autocorrelation function for an MA(q) time series
qi
qihh
q
ii
hq
ihii
0
if0 0
2
0
Comment
“cuts off” to zero after lag q.
-0.4
-0.2
0
0.2
0.4
0.6
0.8
1
1.2
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30
q
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The Autoregressive Time series of order p, AR(p)
where {ut|t T} is a white noise time series with variance 2.
Let {xt|t T} be defined by the equation.
2211 tptpttt uxxxx
Then {xt|t T} is called a Autoregressive time series of order p. (denoted by AR(p))
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The mean value of a stationary AR(p) series
p
txE
211
The Autocovariance function (h) of a stationary AR(p) series
Satisfies the equations:
21 10 pp
101 1 pp
212 1 pp
and
011 ppp
phhh p 11 for h > p
Yule Walker Equations
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2
1
01 1 p p
with
phhh p 11for h > p
111 1 pp
212 1 pp
111 ppp
The Autocorrelation function (h) of a stationary AR(p) series
Satisfies the equations:
and
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or:
h
pp
hh
rc
rc
rch
111
22
11
and c1, c2, … , cp are determined by using the starting values of the sequence (h).
pp xxx 11
pr
x
r
x
r
x111
21
where r1, r2, … , rp are the roots of the polynomial
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Conditions for stationarity
Autoregressive Time series of order p, AR(p)
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The value of xt increases in magnitude and ut eventually becomes negligible.
i.e. 11 ttt uxx
If 1 = 1 and = 0.
The time series {xt|t T} satisfies the equation:
The time series {xt|t T} exhibits deterministic behaviour.
11 tt xx
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For a AR(p) time series, consider the polynomial
pp xxx 11
pr
x
r
x
r
x111
21
with roots r1, r2 , … , rp
then {xt|t T} is stationary if |ri| > 1 for all i.
If |ri| < 1 for at least one i then {xt|t T} exhibits deterministic behaviour.
If |ri| ≥ 1 and |ri| = 1 for at least one i then {xt|t T} exhibits non-stationary random behaviour.
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since:
h
pp
hh
rc
rc
rch
111
22
11
i.e. the autocorrelation function, (h), of a stationary AR(p) series “tails off” to zero.
lim 0h
h
and |r1 |>1, |r2 |>1, … , | rp | > 1 for a stationary AR(p) series then
0
0.2
0.4
0.6
0.8
1
1.2
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30
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Special Cases: The AR(1) time
Let {xt|t T} be defined by the equation.
11 ttt uxx
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Consider the polynomial
xx 11
1
1r
x
with root r1= 1/1
1. {xt|t T} is stationary if |r1| > 1 or |1| < 1 .
2. If |ri| < 1 or |1| > 1 then {xt|t T} exhibits deterministic behaviour.
3. If |ri| = 1 or |1| = 1 then {xt|t T} exhibits non-stationary random behaviour.
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Special Cases: The AR(2) time
Let {xt|t T} be defined by the equation.
2211 tttt uxxx
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Consider the polynomial
2211 xxx
21
11r
x
r
x
where r1 and r2 are the roots of (x)
1. {xt|t T} is stationary if |r1| > 1 and |r2| > 1 .
2. If |ri| < 1 or |1| > 1 then {xt|t T} exhibits deterministic behaviour.
3. If |ri| ≥ 1 for i = 1,2 and |ri| = 1 for at least on i then {xt|t T} exhibits non-stationary random behaviour.
This is true if 1+2 < 1 , 2 –1 < 1 and 2 > -1.These inequalities define a triangular region for 1 and 2.
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Patterns of the ACF and PACF of AR(2) Time SeriesIn the shaded region the roots of the AR operator are complex
h kk
h kk
h kk
h kk
1
21
-1
2-2
III
IIIIV
2
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The Mixed Autoregressive Moving Average Time Series of order p,q The ARMA(p,q) series
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The Mixed Autoregressive Moving Average Time Series of order p, ARMA(p,q)
Let 1, 2, … p , 1, 2, … p , denote p + q +1 numbers (parameters).
Let {ut|t T} denote a white noise time series with variance 2.
– independent– mean 0, variance 2.
Let {xt|t T} be defined by the equation. 2211 ptpttt xxxx
Then {xt|t T} is called a Mixed Autoregressive- Moving Average time series - ARMA(p,q) series.
2211 qtqttt uuuu
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Mean value, variance, autocovariance function,
autocorrelation function of anARMA(p,q) series
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Similar to an AR(p) time series, for certain values of the parameters 1, …, p an ARMA(p,q) time series may not be stationary.
An ARMA(p,q) time series is stationary if the roots (r1, r2, … , rp ) of the polynomial
(x) = 1 – 1x – 2x2 - … - p xp
satisfy | ri| > 1 for all i.
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Assume that the ARMA(p,q) time series {xt|t T} is stationary:
Let = E(xt). Then
2211 ptpttt xExExExE
21 p
1 21 p
1 2
1tp
E x
2211 qtqttt uEuEuEuE
0000 21 q
or
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The Autocovariance function, (h), of a stationary
mixed autoregressive-moving average time series {xt|t T} be determined by the equation:
ptpttt xxxx 2211
Thus
p 211 now
11 ptptt xxx
qtqttt uuuu 2211
qtqttt uuuu 2211
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Hence
tht xxEh
phtpht xxE 11
tqhtqhththt xuuuu 2211
tphtptht xxExxE 11
tqhtqthttht xuExuExuE 11
phh p 11
qhhh uxquxux 11
thtux xuEh where
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ptptht xxuE 11
qtqttt uuuu 2211
pthtptht xuExuE 11
qthtqthttht uuEuuEuuE 11
phh uxpux 11
qhhh uuquuuu 11
thtux xuEh note
.0 if 0 where hxuEh thtux
.0 if 0
.0 if and
2
h
huuEh thtuu
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We need to calculate:
quxuxux ,,1,0
20 ux
hux note phh uxpux 11
qhhh uuquuuu 11
.0 if 0 and hhux
.0 if 0
.0 if 2
h
hhuu
222201 uxux
222 012 uxuxux
22
22
2
222 etc
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The autocovariance function (h) satisfies:
phhh p 11
qhhh uxquxux 11
For h = 0, 1. … , q:
pp 10 1 quxquxux 10 1
101 1 pp 101 quxqux
pqqq p 11 0uxq
for h > q:
phhh p 11
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We then use the first (p + 1) equations to determine: (0), (1), (2), … , (p)
We use the subsequent equations to determine:(h) for h > p.
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Example:The autocovariance function, (h), for an ARMA(1,1) time series:
11 hh 11 hh uxux
For h = 0, 1:
10 1 10 1 uxux
01 1 01 ux
for h > 1: 11 hh
or 10 1 2
1112
01 1 21
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Substituting (0) into the second equation we get:
or
21
2111
211 11
22
1
1111
1
11
Substituting (1) into the first equation we get:
2111
222
1
11111 1
10
22
1
1112
12
111111
1
111
22
1
1121
1
21
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for h > 1: 11 hh
22
1
111111 1
112
22
1
1111211 1
123
22
1
1111111 1
11
hhh
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The Backshift Operator B
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Consider the time series {xt : t T} and Let M denote the linear space spanned by the set of random variables {xt : t T}
(i.e. all linear combinations of elements of {xt : t T} and their limits in mean square).
M is a vector space
Let B be an operator on M defined by:
Bxt = xt-1.
B is called the backshift operator.
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Note: 1.
2. We can also define the operator Bk withBkxt = B(B(...Bxt)) = xt-k.
3. The polynomial operator p(B) = c0I + c1B + c2B2 + ... + ckBk
can also be defined by the equation.p(B)xt = (c0I + c1B + c2B2 + ... + ckBk)xt . = c0Ixt + c1Bxt + c2B2xt + ... + ckBkxt
= c0xt + c1xt-1 + c2xt-2 + ... + ckxt-k
ktktt xcxcxcB
21 21
ktktt BxcBxcBxc 21 21
11211 21 ktktt xcxcxc
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4. The power series operator p(B) = c0I + c1B + c2B2 + ...
can also be defined by the equation.p(B)xt = (c0I + c1B + c2B2 + ... )xt
= c0Ixt + c1Bxt + c2B2xt + ...
= c0xt + c1xt-1 + c2xt-2 + ...
5. If p(B) = c0I + c1B + c2B2 + ... and q(B) = b0I + b1B + b2B2 + ... are such that
p(B)q(B) = I i.e. p(B)q(B)xt = Ixt = xt than q(B) is denoted by [p(B)]-1.
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Other operators closely related to B:
1. F = B-1 ,the forward shift operator, defined by Fxt = B-1xt = xt+1 and
2. = I - B ,the first difference operator, defined by xt = (I - B)xt = xt - xt-1 .
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The Equation for a MA(q) time series
xt= 0ut + 1ut-1 +2ut-2 +... +qut-q + can be written
xt= (B) ut + where
(B) = 0I + 1B +2B2 +... +qBq
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The Equation for a AR(p) time series
xt= 1xt-1 +2xt-2 +... +pxt-p + +ut
can be written
(B) xt= + ut
where
(B) = I - 1B - 2B2 -... - pBp
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The Equation for a ARMA(p,q) time series
xt= 1xt-1 +2xt-2 +... +pxt-p + + ut + 1ut-1 +2ut-2 +... +qut-q
can be written
(B) xt= (B) ut + where
(B) = 0I + 1B +2B2 +... +qBq
and
(B) = I - 1B - 2B2 -... - pBp
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Some comments about the Backshift operator B
1. It is a useful notational device, allowing us to write the equations for MA(q), AR(p) and ARMA(p, q) in a very compact form;
2. It is also useful for making certain computations related to the time series described above;
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The partial autocorrelation function
A useful tool in time series analysis
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The partial autocorrelation function
Recall that the autocorrelation function of an AR(p) process satisfies the equation:
x(h) = 1x(h-1) + 2x(h-2) + ... +px(h-p)
For 1 ≤ h ≤ p these equations (Yule-Walker) become:x(1) = 1 + 2x(1) + ... +px(p-1)
x(2) = 1x(1) + 2 + ... +px(p-2)
...
x(p) = 1x(p-1)+ 2x(p-2) + ... +p.
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In matrix notation:
pxx
xx
xx
x
x
x
pp
p
p
p
2
1
121
211
111
2
1
These equations can be used to find 1, 2, … , p, if the time series is known to be AR(p) and the autocorrelation x(h)function is known.
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In this case p
ppp ,,, 21
If the time series is not autoregressive the equations can still be used to solve for 1, 2, … , p, for any value of p 1.
are the values that minimizes the mean square error:
2
1
)()(...p
ixit
pixt xxEESM
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121
211
111
21
211
111
)(
kk
k
k
kkk
xx
xx
xx
xxx
xx
xx
kkkk
Definition: The partial auto correlation function at lag k is defined to be:
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Comment:
The partial auto correlation function, kk is determined from the auto correlation function, (h)
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Some more comments:
1. The partial autocorrelation function at lag k, kk, can be interpreted as a corrected autocorrelation between xt and xt-k conditioning on the intervening variables xt-1, xt-2, ... ,xt-k+1 .
2. If the time series is an AR(p) time series than
kk = 0 for k > p
3. If the time series is an MA(q) time series than
x(h) = 0 for h > q
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A General Recursive Formula for Autoregressive Parameters and the
Partial Autocorrelation function (PACF)
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Letkk
kk
kkk ,,,, 321
denote the autoregressive parameters of order k satisfying the Yule Walker equations:
kkk
kkk13221
223121 kkk
kkk
kkk
kk
kk
kk 332211
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Then it can be shown that:
k
jj
kj
k
jjk
kjk
kkkk
1
11
1,111
1
and
kjkjkkk
kj
kj ,,2 ,1 11,1
1
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Proof:
The Yule Walker equations:
kkk
kkk13221
223121 kkk
kkk
kkk
kk
kk
kk 332211
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In matrix form:
kkk
k
k
kk
k
k
22
1
21
2
1
1
1
1
kkk ρβΡ or
k
k
kk
k
k
k
kk
k
k
k
22
1
21
2
1
and ,
1
1
1
ρβΡ
kkk ρΡβ1
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The equations for
1
2
11
12
11
1
1
1
1
1
kkk
k
k
kk
k
k
1,111
13
12
11 ,,,,
kkkk
kkk
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11,1
11
1or
k
k
kk
k
k
kk
ρβ
Aρ
AρΡ
001
000
100
where
A and
113
12
11
11 ,,,, k
kkkkk β
The matrix A reverses order
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kkkk
kk ρAρβΡ
1,11
1
The equations may be written
11,11
1
kkkkk βAρ
Multiplying the first equations by
kkkkkkk
k βρΡAρΡβ
11
1,11
1
1
kΡ
or kkkk
kk AρΡββ1
1,11
1
kkkk
k ρΡAβ1
1,1
k
kkk Aββ 1,1
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Substituting this into the second equation
or
11,11,1
kkkk
kkkk AββAρ
kkk
kkkk Aβρβρ
11,1 1
and kk
kkk
kk
ρβ
Aβρ
1 1
1,1
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Hence
k
jj
kj
k
jjk
kjk
kkkk
1
11
1,111
1
and
kjkjkkk
kj
kj ,,2 ,1 11,1
1
kkk
kk Aβββ 1,11
or
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Some Examples
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Example 1: MA(1) time seriesSuppose that {xt|t T} satisfies the following
equation:
xt = 12.0 + ut + 0.5 ut – 1
where {ut|t T} is white noise with = 1.1.Find:1. The mean of the series,2. The variance of the series,3. The autocorrelation function.4. The partial autocorrelation function.
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SolutionNow {xt|t T} satisfies the following equation:
xt = 12.0 + ut + 0.5 ut – 1
Thus:
1. The mean of the series,
= 12.0
The autocovariance function for an MA(1) is
222 21
22
1 0.5 1.1 01 0 1.5125 0
1 0.5 1.1 1 0.605 1
0 1 0 1 0 1
hh h
h h h h
h h h
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Thus:
2. The variance of the series,
(0) = 1.5125
and
3. The autocorrelation function is:
0.6051.5125
1 0 1 0
1 0.4 10
0 1 0 1
h hh
h h h
h h
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( )
1 1 1
1 1 2
1 2
1 1 1
1 1 2
1 2 1
kkk k
k k k
k
k
k k
4. The partial auto correlation function at lag k is defined to be:
Thus (1)11 1
11 0.4
1
2 2(2)
22 2 2 2
1 1
1 2 2 1 0.4 0.16.19048
1 1 1 0.4 0.841 1
1 1
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(3)33 3
1 1 1 1 0.4 0.4
1 1 2 0.4 1 0
2 1 3 0 0.4 0 0.0640.0941
1 .4 0 0.681 1 2
.4 1 .41 1 1
0 .4 12 1 1
(4)44 4
1 1 2 1 1 .4 0 .4
1 1 1 2 .4 1 .4 0
2 1 1 3 0 .4 1 0
3 2 1 4 0 0 .4 0 0.02560.0469
1 .4 0 0 0.54561 1 2 3
.4 1 .4 01 1 1 2
0 .4 1 .42 1 1 1
0 0 .4 13 2 1 1
(5)55 5
0.010240.0234
0.4368
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66 77 88 990.0117, 0.0059, 0.0029, 0.0015
10,10 11,11 12,120.0007, 0.0004, 0.00029
-0.4
-0.2
0
0.2
0.4
0.6
0.8
1
1.2
0 1 2 3 4 5 6 7 8 9 10 11
Graph: Partial Autocorrelation function kk
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Exercise: Use the recursive method to calculate kk
111
1 1, 1
1
1
kk
k j k jjk
k k k kkj j
j
and
11, 1 1 1, 2, , k k k
j j k k k j j k
11 1,1 1we start with
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Exercise: Use the recursive method to calculate kk
212 2 1 12 2,2 21
1 1
0.4.19048
1 1 0.4
and2 1 1
1 1 2.2 1 1j
1 .19048 0.4
1.19048 0.4 .0.476192
2 23 3 1 2 1 13 3,3 2 2
1 1 2 2
0.0941, etc1
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Example 2: AR(2) time series
Suppose that {xt|t T} satisfies the following equation:
xt = 0.4 xt – 1 + 0.1 xt – 2 + 1.2 + ut
where {ut|t T} is white noise with = 2.1.Is the time series stationary?Find:1. The mean of the series,2. The variance of the series,3. The autocorrelation function.4. The partial autocorrelation function.
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1. The mean of the series
1 2
1.22.4
1 1 0.4 0.1
3. The autocorrelation function.Satisfies the Yule Walker equations
1 1 2 1 1
2 1 1 2 1
1 0.4 0.1
1 0.4 0.1
1 1 2 1 1then 0.4 0.1
where h h h h h
h h
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hence
1
2
0.40.4444
0.90.4
0.4 0.1 2.7780.9
1 1 2 1 1then 0.4 0.1
where h h h h h
h h
h 0 1 2 3 4 5 6
h 1.0000 0.4444 0.2778 0.1556 0.0900 0.0516 0.0296
h 7 8 9 10 11 12 13
h 0.0170 0.0098 0.0056 0.0032 0.0018 0.0011 0.0006
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2. the variance of the series
2 2
1 1 2 1
2.10 5.7522
1 1 0.4 0.4444 0.1 0.2778
4. The partial autocorrelation function.
1,1 1 0.4444
1
1 22,2
1
1
1 1 0.4444
0.4444 .27780.1000
1 0.44441
0.4444 11
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1 1
1 2
2 1 33,3
1 2
1 1
2 1
1 1 0.4444 0.4444
1 0.4444 1 0.2778
0.2778 0.4444 0.15560
1 1 0.4444 0.2778
1 0.4444 1 0.4444
1 0.2778 0.4444 1
,in fact 0 for 3k k k
The partial autocorrelation function of an AR(p) time series “cuts off” after p.
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Example 3: ARMA(1, 2) time series
Suppose that {xt|t T} satisfies the following equation:
xt = 0.4 xt – 1 + 3.2 + ut + 0.3 ut – 1 + 0.2 ut – 1
where {ut|t T} is white noise with = 1.6.Is the time series stationary?Find:1. The mean of the series,2. The variance of the series,3. The autocorrelation function.4. The partial autocorrelation function.