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NI-DSP SRM for LabVIEW for Windows Index-2 © National Instruments Corporation
indexing output arrays to obtain results,
Part 4: 2-10 to 2-12
linking, Part 4: 2-7 to 2-8
makelib.bat file, Part 4: 2-8
memory management, Part 4: 2-3
parameter guidelines, Part 4: 2-2 to 2-3
prototypes for customizable functions,
Part 4: 3-1 to 3-3
source code creation, Part 4: 2-1 to 2-3
steps for creating, Part 4: 2-1
using WE DSP32C assembly language,
Part 4: 2-3 to 2-4
Custom VI. See DSP Custom VI.
customer communication, xv, B-1
D
data acquisition functions, Part 4: 3-3
data buffers. See DSP Handle Clusters.
data transfer. See memory management and data
transfer.
data types
DSP Handle Cluster as array data type,
Part 2: 1-4
icons representing (table), xiii
deleting (replacing) functions in NIDSP.fnc file,
Part 4: 2-5
Developer Toolkit, xv
DFT (Discrete Fourier Transform), Part 3: 1-4 to 1-5
Dispatch application, Part 4: 1-1, Part 4: 2-6
documentation
conventions used in manual, xii-xiii
organization of manual, xi-xii
related documentation, xiv
DSP Absolute function, Part 3: 2-4
DSP Add function
DSP Handle Cluster input/output example,
Part 2: 1-5
purpose and use, Part 3: 2-5
DSP Allocate Memory function, Part 3: 2-6
DSP Blackman Harris Window VI, Part 3: 2-8
DSP Blackman Window VI, Part 3: 2-7
DSP Butterworth Coefficients VI, Part 3: 2-9 to 2-10
DSP Chebyshev Coefficients VI, Part 3: 2-10 to 2-11
DSP Clip VI, Part 3: 2-11
DSP Complex FFT VI, Part 3: 2-12
DSP Convolution VI, Part 3: 2-13
DSP Correlation VI, Part 3: 2-14
DSP Cross Power VI, Part 3: 2-15
DSP Custom VI
calling from LabVIEW interface, Part 4: 2-10
definition, Part 4: 2-9
executing from LabVIEW interface, Part 4: 2-12
purpose and use, Part 3: 2-16
DSP Decimate VI, Part 3: 2-17
DSP Deconvolution VI, Part 3: 2-18
DSP Derivative VI, Part 3: 2-19
DSP Divide VI, Part 3: 2-20
DSP DMA Copy(DSP to LV) VI, Part 4: 4-3
DSP DMA Copy(LV to DSP) VI; Part 4: 4-4
DSP Elliptic Coefficients VI, Part 3: 2-21 to 2-22
DSP Equi-Ripple BandPass VI, Part 3: 2-23 to 2-24
DSP Equi-Ripple BandStop VI, Part 3: 2-25 to 2-26
DSP Equi-Ripple HighPass VI, Part 3: 2-27 to 2-28
DSP Equi-Ripple LowPass VI, Part 3: 2-29
DSP Exact Blackman Window VI, Part 3: 2-30
DSP Exponential Window VI, Part 3: 2-31
DSP FHT VI, Part 3: 2-32
DSP Flat Top Window VI, Part 3: 2-33
DSP Force Window VI, Part 3: 2-34
DSP Free Memory VI, Part 3: 2-34
DSP Gaussian White Noise VI, Part 3: 2-35
DSP General Cosine Window VI, Part 3: 2-36
DSP Hamming Window VI, Part 3: 2-37
DSP Handle Clusters
allocation examples, Part 2: 1-4
array data type, Part 2: 1-4
bundling for LabVIEW interface,
Part 4: 2-8 to 2-9
definition, Part 2: 1-2, Part 2: 1-3
hexadecimal encoding, Part 2: 1-3
illustration, Part 2: 1-3
improving execution speed of DSP VIs,
Part 2: 1-7
input/output, Part 2: 1-5
memory management and data transfer,
Part 2: 1-2 to 1-4
obtaining valid DSP Handle Cluster, Part 2: 1-4
output data buffers, Part 2: 1-5
values not to be changed, Part 2: 1-3
Z in, Z out naming convention, Part 2: 1-5
DSP Handle to Address VI; Part 3: 2-38
DSP Hanning Window VI, Part 3: 2-38
DSP IIR Filter VI, Part 3: 2-39 to 2-40
DSP Impulse Pattern VI, Part 3: 2-41
DSP Impulse Train Pattern VI, Part 3: 2-42
DSP Index Memory VI, Part 3: 2-43
DSP Init Memory VI, Part 3: 2-44
DSP Integral VI, Part 3: 2-45
DSP Inv Chebyshev Coeff VI, Part 3: 2-46 to 2-47
DSP Inverse FFT VI, Part 3: 2-47
DSP Inverse FHT VI, Part 3: 2-48
DSP Kaiser-Bessel Window VI,Part 3: 2-49
DSP Linear Evaluation VI, Part 3: 2-50
DSP Load VI, Part 3: 2-50
DSP Log VI, Part 3: 2-51
DSP Max & Min VI, Part 3: 2-52
DSP Median Filter VI, Part 3: 2-53
DSP Multiply VI, Part 3: 2-54
DSP Parks McClellan VI, Part 3: 2-55 to 2-57
DSP Polar to Rectangular VI; Part 3: 59
DSP Polynomial Evaluation VI, Part 3: 2-58
DSP Power Spectrum VI, Part 3: 2-59
DSP Product VI, Part 3: 2-59
DSP Pulse Pattern VI, Part 3: 2-60