AVR
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Average input X over evaluation cycles.
[SPU AVR X TYP T RS OUT Y]
| dir. | name | description | type | default | in | X | a number, vector or matrix containing the data to be averaged | variable |
|---|---|---|---|---|---|---|---|---|
| in | TYP | a number or string; defines the averaging method | constant | |||||
| in | T | averaging parameter (number); depends on method | variable, only for TYP=2 | |||||
| in | RS | reset flag (number) | variable, only checked on SPU start | |||||
| out | Y | averaged input X; same type as X |
- Description
The averaging algorithm is defined by the inputs TYP and T. The atom averages the elements X[i,j]t over evaluation cycles t (i=row index, j=column index, t=cycle counter) and stores the averaged value in the element Y[i,j]t.
The cycle counter t is initialized with 0 and incremented by 1 after each evaluation cycle. The cycle counter is reset, if the input RS is set to a value greater than 0. The input RS is checked each time the SPU is started.
- infinite average
- TYP=
0orlinear - T=
0 -
Y
[
i
,
j
]
t
=
{
X
[
i
,
j
]
t
if
t
=
0
1
t
+
1
(
t
.
Y
[
i
,
j
]
t
−
1
+
X
[
i
,
j
]
t
)
if
t
>
0
{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0\\{\frac {1}{t+1}}(t.Y[i,j]_{t-1}+X[i,j]_{t})&{\mbox{if }}t>0\end{cases}}}
- running average
- TYP=
0orlinear - T>
0; T is the (integer) number of averaging cycles -
Y
[
i
,
j
]
t
=
{
1
t
+
1
∑
z
=
0
t
X
[
i
,
j
]
z
if
0
⩽
t
<
T
1
T
∑
z
=
0
T
−
1
X
[
i
,
j
]
t
−
z
if
t
⩾
T
{\displaystyle Y[i,j]_{t}={\begin{cases}{\frac {1}{t+1}}\sum _{z=0}^{t}X[i,j]_{z}&{\mbox{if }}0\leqslant t<T\\{\frac {1}{T}}\sum _{z=0}^{T-1}X[i,j]_{t-z}&{\mbox{if }}t\geqslant T\end{cases}}}
- exponential average
- TYP=
1orexponential 0<T<1; T is the averaging factor-
Y
[
i
,
j
]
t
=
{
X
[
i
,
j
]
t
if
t
=
0
(or
T
out of range)
T
.
Y
[
i
,
j
]
t
−
1
+
(
1
−
T
)
.
X
[
i
,
j
]
t
if
t
>
0
{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0{\mbox{ (or }}T{\mbox{ out of range)}}\\{\sqrt {T}}.Y[i,j]_{t-1}+(1-{\sqrt {T}}).X[i,j]_{t}&{\mbox{if }}t>0\end{cases}}}
- minimum
- TYP=
2orminimum - T is not used
-
Y
[
i
,
j
]
t
=
{
X
[
i
,
j
]
t
if
t
=
0
m
i
n
(
Y
[
i
,
j
]
t
−
1
,
X
[
i
,
j
]
t
)
if
t
>
0
{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0\\min(Y[i,j]_{t-1},X[i,j]_{t})&{\mbox{if }}t>0\end{cases}}}
- maximum
- TYP=
3ormaximum - T is not used
-
Y
[
i
,
j
]
t
=
{
X
[
i
,
j
]
t
if
t
=
0
m
a
x
(
Y
[
i
,
j
]
t
−
1
,
X
[
i
,
j
]
t
)
if
t
>
0
{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0\\max(Y[i,j]_{t-1},X[i,j]_{t})&{\mbox{if }}t>0\end{cases}}}
![{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0\\{\frac {1}{t+1}}(t.Y[i,j]_{t-1}+X[i,j]_{t})&{\mbox{if }}t>0\end{cases}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/1ebb989e256d6d3f8f3ee075730540133d20c3f6)
![{\displaystyle Y[i,j]_{t}={\begin{cases}{\frac {1}{t+1}}\sum _{z=0}^{t}X[i,j]_{z}&{\mbox{if }}0\leqslant t<T\\{\frac {1}{T}}\sum _{z=0}^{T-1}X[i,j]_{t-z}&{\mbox{if }}t\geqslant T\end{cases}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/171c71b4a374cbf81e671334844649a4e8012d82)
![{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0{\mbox{ (or }}T{\mbox{ out of range)}}\\{\sqrt {T}}.Y[i,j]_{t-1}+(1-{\sqrt {T}}).X[i,j]_{t}&{\mbox{if }}t>0\end{cases}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/d62837f4190e64922bdef8b74c900ea372418458)
![{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0\\min(Y[i,j]_{t-1},X[i,j]_{t})&{\mbox{if }}t>0\end{cases}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/e4fded79452f5091c73c4c093afe423261f4b23e)
![{\displaystyle Y[i,j]_{t}={\begin{cases}X[i,j]_{t}&{\mbox{if }}t=0\\max(Y[i,j]_{t-1},X[i,j]_{t})&{\mbox{if }}t>0\end{cases}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/a35f971f45e1f926c04e60c39292028c5a8f8739)
- See also
<SP-atoms>
