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A
For Loop executes a subdiagram a set number of
times.
shows a
For Loop in
LabVIEW, a flow chart equivalent of the
For Loop functionality, and a pseudo code example of the functionality of
the
For Loop .
The
For Loop is located on the
Functions>>All Functions>>Structures palette. You also
can place a
While Loop on the block diagram,
right-click the border of the
While Loop , and
select
Replace with For Loop from the shortcut menu
to change a
While Loop to a
For
Loop . The value in the
count terminal (an
input terminal), shown in
, indicates how
many times to repeat the subdiagram.
The
iteration terminal (an output terminal), shown
in
, contains the number of completed
iterations. The iteration count always starts at zero. Duringthe first iteration, the iteration terminal returns
0 .
The
For Loop differs from the
While
Loop in that the
For Loop executes a set
number of times. A
While Loop stops executing the
subdiagram only if the value at the conditional terminal exists.
The
For Loop in
generates a
random number every second for
seconds and displays the random numbers in a numeric indicator.
The
Wait Until Next ms Multiple function, shown
in
, monitors a millisecond counter and
waits until the millisecond counter reaches a multiple of theamount you specify. Use this function to synchronize
activities. Place this function within a loop to control theloop execution rate.
The
Wait (ms) function, shown in
, adds the wait time to the code execution
time. This can cause a problem if code execution time isvariable.
Time Delay Express VI, located on the
Functions>>Execution Control palette, behaves
similar to the
Wait (ms) function with the
addition of built-in error clusters. Refer to
Clusters for more information about error
clusters.LabVIEW can represent numeric data types as signed or unsigned integers (8-bit, 16-bit, or 32-bit), floating-point numericvalues (single-, double-, or extended-precision), or complex numeric values (single-, double-, or extended-precision). Whenyou wire two or more numeric inputs of different representations to a function, the function usually returnsoutput in the larger or wider format. The functions coerce the smaller representations to the widest representation beforeexecution, and LabVIEW places a coercion dot on the terminal where the conversion takes place.
For example, the
For Loop count terminal is a
32-bit signed integer. If you wire a double-precision,floating-point numeric to the count terminal, LabVIEW converts
the numeric to a 32-bit signed integer. A coercion dot appearson the count terminal of the first
For Loop , as
shown in
.
If you wire two different numeric data types to a numeric function that expects the inputs to be the same data type,LabVIEW converts one of the terminals to the same representation as the other terminal. LabVIEW chooses therepresentation that uses more bits. If the number of bits is the same, LabVIEW chooses unsigned over signed.
In the example in
, a 32-bit
signed integer (I32) and a double-precision, floating-pointnumeric value (DBL) are wired to the
Divide function. The 32-bit signed integer is coerced since it uses
fewer bits than the double-precision, floating-point numericvalue.
To change the representation of a numeric object, right-click
the object and select
Representation from the
shortcut menu. Select the data type that best represents the
data.ut data types.
When LabVIEW converts double-precision, floating-point numeric
values to integers, it rounds to the nearest integer. LabVIEWrounds
x.5 to the nearest even integer. For
example, LabVIEW rounds
to
and
to
.
Refer to the Data Types section of Introduction to LabVIEW, of thismanual or to the LabVIEW Help for more information about data types.
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