f (linear frequency). See frequencies
fn (normalized cutoff or band edge frequency vector)
See cutoff frequencies
fn0 (normalized cutoff frequency)
See cutoff frequencies
fn1 (normalized lower cutoff frequency)
See cutoff frequencies
fn2 (normalized upper cutoff frequency)
See cutoff frequencies
fnyq (Nyquist frequency). See frequencies
Fs (sample frequency or rate)
See sample periods
M (frame size). See frame sizes and matrices
Mi (input frame size). See frame sizes
mn (normalized magnitude vector)
See magnitudes
Mo (output frame size). See frame sizes
N (number of channels)
See sample vectors and matrices
(digital frequency). See frequencies
(angular frequency). See frequenciesp (passband edge frequency) See edge frequencies
p1 (lower passband edge frequency) See edge frequencies
p2 (upper passband edge frequency) See edge frequencies
s (stopband edge frequency) See edge frequencies
s1 (lower stopband edge frequency) See edge frequencies
s2 (upper stopband edge frequency) See edge frequencies
Rp (passband ripple). See passband ripple <1> <2>
Rs (stopband attenuation)
See stopband attenuation
T (signal period). See periods
T (tunable parameter). See tuning parameters
Tf (frame period). See frame periods
Tfi (input frame period). See frame periods
Tfo (output frame period). See frame periods
Ts (sample period). See sample periods <1> <2>
Tsi (input sample period). See sample periods
Tso (output sample period). See sample periods
Numerics
inserting <1> <2> <3>
outputting
Counter block
Discrete Impulse block
Integer Delay block
N-Sample Enable block
Signal From Workspace block <1> <2>
padding with <1> <2>
1s, outputting
2-norm
A
adaptive filter designs
blocks for
FIR
Kalman
LMS
RLS
adaptive filters
Adaptive Filters library
addition, cumulative
algebraic loop errors
algorithmic delay
adjustable
and initial conditions
basic
excess
relation to latency
zero
Analog Filter Design block <1> <2> <3>
analog filter designs <1> <2> <3>
See also filter designs, continuous-time
analytic signal
Analytic Signal block
angular frequency
defined
See also periods
arbitrary shape filter designs
digital, available parameters
tabulated
See also filter band configurations, arbitrary shape
arrays
exporting matrix data to
importing
attenuation, stopband <1> <2>
audio
exporting <1> <2> <3>
importing <1> <2>
autocorrelation
and Levinson-Durbin recursion
of a real vector
sequence
Autocorrelation block
Autocorrelation LPC block
autocorrelation method
auto-promoting rates
autoregressive models
using Burg AR Estimator block
using Burg Method block
using the Covariance AR Estimator block
using the Covariance Method block
using the Modified Covariance AR Estimator block
using the Modified Covariance Method block
using the Yule-Walker AR Estimator block
using the Yule-Walker Method block
B
band configurations
See filter band configurations
Band edge frequencies parameter
length of <1> <2>
See also parameters
bandpass filter designs
analog, available parameters
digital, available parameters
tabulated
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital IIR Filter Design block
bandstop filter designs
analog, available parameters
digital, available parameters
tabulated
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital IIR Filter Design block
Bartlett windows
basic operations
batch processing
binary clock signals
bins, histogram
Biquadratic Filter block
Blackman windows
block diagrams, creating <1> <2>
blocks
connecting
multirate
parameters for
single-rate
Boxcar windows
Buffer block <1> <2> <3>
initial state of
Buffer overlap parameter
negative values for
buffering <1> <2> <3>
and rate conversion
blocks for
causing unintentional rate conversions
example
FIFO (first input, first output) register
internally
LIFO (last input, first output) register
overlapping <1> <2>
to create a frame-based signal
with alteration of the signal <1> <2>
with Delay Line block
with preservation of the signal
with Queue block
with Stack block
with Triggered Delay Line block
Buffers library
Burg AR Estimator block
Burg Method block
butter <1> <2>Butterworth filter designs
analog <1> <2>
band configurations for <1> <2>
digital
magnitude response of
tabulated
using Analog Filter Design block
using Digital IIR Filter Design block
C
canonical forms <1> <2>
channels
in a frame-matrix
of a sample-based signal
cheby1 <1> <2>cheby2 <1> <2>Chebyshev approximation
Chebyshev type I filter designs
analog <1> <2>
band configurations for <1> <2>
digital
magnitude response of
tabulated
using Analog Filter Design block
using Digital IIR Filter Design block
Chebyshev type II filter designs
analog <1> <2>
band configurations for <1> <2>
digital
magnitude response of
tabulated
using Analog Filter Design block
using Digital IIR Filter Design block
Chebyshev windows <1> <2>
Check Signal Attributes block
Chirp block
Cholesky Factorization block
Cholesky Inverse block
Cholesky Solver block
clocks
binary
multiphase
code generation
and contiguous memory
generic real-time (GRT)
minimizing size of
using Real Time Workshop (RTW)
color coding sample periods
complex analytic signal
Complex Cepstrum block
Complex Exponential block
complex exponentials <1> <2>
compound filters
computational delay
concatenating
to create multichannel signals <1> <2>
Constant Diagonal Matrix block
Constant Ramp block
constants
generating
invariant (non-tunable)
matrix <1> <2>
precomputing
ramp
Contiguous Copy block
contiguous memory
defined
continuous-time filter designs
See filter designs, continuous-time
continuous-time signals
continuous-time source blocks
control signals
for Triggered Shift Register block
for Triggered Signal From Workspace block
for Triggered Signal To Workspace block
controller canonical forms
conventions
technical
time and frequency
conventions in our documentation (table)
Convert 1-D to 2-D block
Convert 2-D to 1-D block
Convert Complex DSP To Simulink block
Convert Complex Simulink To DSP block
converting
frame rates. See rate conversion
sample rates. See rate conversion
convolution
of two real vectors
Convolution block
correlation
of two real vectors
Correlation block
correlation matrices
Counter block
Covariance AR Estimator block
Covariance Method block
Create Diagonal Matrix block
creating signals
Cumulative Sum block
cutoff frequencies
upper
D
dB Gain block
dB, converting to
dBm, converting to
DC component of an analytic signal
DCT block
DCTs
computing
decimation
process of
using FIR Decimation block
using FIR Rate Conversion block
default settings, Simulink
delay
algorithmic
computational
fractional <1> <2>
generating <1> <2> <3>
integer
rebuffering <1> <2>
relation to latency
types of
Delay Line block <1> <2> <3>
demos
MATLAB
running
Demos library
Design method parameter
Detrend block
diagonal matrix constants
dialog boxes, opening
Difference block
difference, between elements in a vector
differentiator filter designs
band configuration of
tabulated
using Least Squares FIR Filter Design block
using Remez FIR Filter Design block
digital filter designs
See filter designs, discrete-time
Digital FIR Filter Design block <1> <2> <3>
Digital FIR Raised Cosine Filter Design block <1> <2>
digital frequency
defined
See also periods
Digital IIR Filter Design block <1> <2> <3> <4>
Direct-Form II Transpose Filter block
as used by Digital FIR Filter Design block <1> <2>
as used by Digital FIR Raised Cosine Filter Design block
as used by Least Squares FIR Filter Design block
as used by Remez FIR Filter Design block
as used by Yule-Walker IIR Filter Design block
initial conditions for
discrete cosine transforms. See DCTs
Discrete Impulse block
discrete sample time, defined
discrete-time blocks
nonsource
source
discrete-time filter designs
See filter designs, discrete-time
discrete-time signals
characteristics
defined
terminology <1> <2>
See also signals
discretizing a continuous-time signal
Display block
displaying
blocks for
frame-based data
matrices as images
docdocumentation
Signal Processing Toolbox
Downsample block <1> <2> <3>
downsampling <1> <2> <3>
See also rate conversion
DSP Blockset
accessing
documentation
features
getting started with
installation
organization
overview
required products
DSP Constant block
DSP Sinks library
DSP Sources library
dsp_linksdsplib <1> <2> <3>dspstartup M-file <1> <2> <3>editing
Dyadic Analysis Filter Bank block <1> <2>
Dyadic Synthesis Filter Bank block <1> <2>
E
edge frequencies
of analog filters
edge frequencies, of analog filters
ellip <1> <2>elliptic filter designs
analog <1> <2>
band configurations for <1> <2>
digital
magnitude response of
tabulated
using Analog Filter Design block
using Digital IIR Filter Design block
equiripple filter designs <1> <2>
frequency response of
error minimization <1> <2>
errors
algebraic loop
discrete-time source block
due to continuous-time input to a discrete-time block <1> <2>
due to insufficient audio buffer size
sample-rate mismatch
estimation
nonparametric <1> <2>
parametric
using Burg AR Estimator block
using Burg Method block
using Covariance AR Estimator block
using Covariance Method block
using Modified Covariance AR Estimator block
using Modified Covariance Method block
using Yule-Walker AR Estimator block
using Yule-Walker Method block
Estimation library
Event-Count Comparator block
events, triggering
for N-Sample Enable block <1> <2>
for Sample and Hold block
for Stack block <1> <2>
for Triggered Shift Register block
for Triggered Signal From Workspace block
for Triggered Signal To Workspace block
examples
filtering
exponentials, complex <1> <2>
exporting
blocks for <1> <2>
sample-based signals
using Triggered Signal To Workspace block
exporting signals
Extract Diagonal block
Extract Triangular Matrix block
F
defined
See also frequencies
features of DSP Blockset
FFT block
FFT length parameter
FFTs
and overlap-add filtering
and overlap-save filtering
computing
filter architectures. See filter realizations <1> <2>
filter band configurations
arbitrary shape
bandpass <1> <2>
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital IIR Filter Design block
bandstop <1> <2>
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital IIR Filter Design block
highpass <1> <2>
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital IIR Filter Design block
lowpass <1> <2>
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital FIR Raised Cosine Filter Design block
using Digital IIR Filter Design block
multiband
using Least Squares FIR Filter Design block
using Remez FIR Filter Design block
table of
filter designs
analog. See filter designs, continuous-time
Butterworth
band configurations for
magnitude response of
using Analog Filter Design block
using
butter <1> <2>using Digital IIR Filter Design block
categories of
Chebyshev type I
band configurations for <1> <2>
magnitude response of
using Analog Filter Design block
using
cheby1 <1> <2>using Digital IIR Filter Design block
Chebyshev type II
band configurations for <1> <2>
example of
magnitude response of
using Analog Filter Design block
using
cheby2 <1> <2>using Digital IIR Filter Design block
continuous-time <1> <2> <3>
available parameters
band configurations for
edge frequency for
passband ripple for
stopband attenuation for
differentiator
using Least Squares FIR Filter Design block
using Remez FIR Filter Design block
digital. See filter designs, discrete-time <1> <2>
discrete-time <1> <2>
band configurations for <1> <2>
classical <1> <2>
FIR <1> <2>
magnitude response of <1> <2>
passband ripple for
Signal Processing Toolbox functions
stopband attenuation for
elliptic
band configurations for <1> <2>
magnitude response of
using Analog Filter Design block
using Digital IIR Filter Design block
using
ellip <1> <2>FIR
arbitrary magnitude response
discrete-time
Remez
using least-squares technique
using Levinson-Durbin block
using Parks-McClellan technique
with prescribed autocorrelation sequence
Hilbert transformer
using Least Squares FIR Filter Design block
using Remez FIR Filter Design block
IIR
continuous-time
discrete-time
using Yule-Walker IIR Filter Design block
least-squares, example of
linear phase <1> <2>
raised cosine
table of
working with
Filter Designs library
filter orders
and Digital FIR Filter Design block
and Digital IIR Filter Design block
Filter Realization Wizard
filter realizations
canonical forms <1> <2>
lattice
transposed direct-form II IIR <1> <2>
using Filter Realization Wizard
Filter Realizations library
Filter type parameter
filtering
adaptive. See adaptive filter designs
by overlap-add method
by overlap-save method
example
multirate
using Direct-Form II Transpose Filter block <1> <2>
using Time-Varying Lattice Filter block
Filtering library
filters
adaptive
FIR Decimation block <1> <2>
FIR filter designs
algorithm for
discrete-time <1> <2>
band configurations for
equiripple
least-squares <1> <2>
linear phase
magnitude response of
using Levinson-Durbin block
using Parks-McClellan technique
with prescribed autocorrelation sequence
FIR Interpolation block <1> <2>
FIR Rate Conversion block <1> <2>
fir1firls <1> <2>firrcosfirst-input, first-output (FIFO) registers
fixed-step solvers <1> <2>
Flip block
fn (normalized cutoff or band edge frequency vector)
See cutoff frequencies
fn (normalized frequency)
defined
See also frequencies
fn0 (normalized cutoff frequency)
See cutoff frequencies
fn1 (normalized lower cutoff frequency)
See cutoff frequencies
fn2 (normalized upper cutoff frequency)
See cutoff frequencies
fnyq (Nyquist frequency)
defined
See also frequencies
Forward Substitution block
frame
defined
See also frame-based signals
frame periods
altered by buffering
altered by unbuffering
constant <1> <2>
converting. See rate conversion
defined <1> <2>
inspecting
inspecting, using the Simulink Probe block
multiple
related to sample period and frame size <1> <2>
frame rates
auto-promoting
See also frame periods
frame sizes
constant <1> <2>
converting
by direct rate conversion
by rebuffering
to maintain constant frame rate <1> <2>
to maintain constant sample rate <1> <2>
See also rate conversion
defined <1> <2>
related to sample period and frame period
frame status
converting
Frame Status Conversion block
frame-based processing
and latency
benefits
frame-based signals
benefits of
changing frame size
converting to sample-based signals <1> <2>
creating
creating from sample-based signals
unbuffering
frame-matrices
format of
frames
changing size of
unbuffering to scalars
Framing parameter
frequencies
normalized <1> <2> <3> <4>
normalized linear
specifying <1> <2>
terminology
See also periods <1> <2> <3>
frequency distributions
computing
frequency response
equiripple
of Yule-Walker IIR Filter Design block
specifying
example of
See also magnitude response
From Wave Device block
From Wave File block
Fs (sample frequency or rate)
defined
See also sample periods
functions, utility
dsp_linksdsplibdspstartup <1> <2> <3>rebuffer_delaystartupstartupsavG
generated code
and contiguous memory
generic real-time (GRT)
size of
generating signals
H
Hann windows
Help Browser, accessing
help, accessing <1> <2>
helpdeskhighpass filter designs
continuous-time
discrete-time
tabulated
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital IIR Filter Design block
Hilbert transformer filter designs
band configuration of
tabulated
using Least Squares FIR Filter Design block
using Remez FIR Filter Design block
Histogram block <1> <2>
histograms, computing
Hz (Hertz)
defined
See also sample periods
I
IDCTs
computing
identity matrices
Identity Matrix block
IFFT block
IFFTs
computing
IIR filter designs
classical
continuous-time
discrete-time <1> <2>
magnitude response of
using Yule-Walker IIR Filter Design block
images, displaying matrices as
importing
arrays
blocks for
frame-based signals
pages of an array
sample-based matrices
sample-based signals <1> <2> <3>
sample-based vectors
scalars
signals <1> <2> <3>
vectors
indexing
to deconstruct multichannel signals
Indexing library
inf parameter settinginfoInherit Complexity block
inheriting sample periods
initial conditions, with basic algorithmic delay
Inline Parameters check box
input frame periods
defined
See also frame periods
input frame sizes. See frame sizes
input periods. See also frame periods
input sample periods. See sample periods
installing the DSP Blockset
Integer Delay block
initial conditions for <1> <2>
interpolating <1> <2>
procedure
InvariantConstants parameterinverse discrete cosine transforms. See IDCTs
K
Kalman Adaptive Filter block
L
latency
due to frame-based processing
example
predicting
reducing
relation to delay
lattice filters
LDL Factorization block
LDL Inverse block
LDL Solver block
least mean-square algorithm
Least Squares FIR Filter Design block <1> <2> <3> <4> <5>
algorithm
and
firlsexample
Least Squares Polynomial Fit block
least-squares technique
length of a vector
defined
See also frame sizes
Levinson-Durbin block
libraries
Adaptive Filters
Buffers
Demos
displaying link information
DSP Sinks
DSP Sources
Estimation
Filter Designs
Filter Realizations
Filtering
Indexing
Linear Prediction
Linear System Solvers
listed
Math Functions
Math Operations
Matrices and Linear Algebra
Matrix Factorizations
Matrix Functions
Matrix Inverses
Matrix Operations
Multirate Filters
opening
Parametric Estimation
Polynomial Functions
Power Spectrum Estimation
Quantizers
Signal Attributes
Signal Management
Signal Operations
Simulink <1> <2>
Statistics <1> <2>
Switches and Counters
Transforms
Library Browser, using
line widths
displaying
linear algebra
linear phase FIR filters
Linear Prediction library
linear prediction, using LPC block
Linear System Solvers library
LMS Adaptive Filter block
LMS algorithm
loop-rolling
lowpass filter designs
continuous-time
differentiator
discrete-time
tabulated
using Analog Filter Design block
using Digital FIR Filter Design block
using Digital FIR Raised Cosine Filter Design block
using Digital IIR Filter Design block
LU Factorization block
LU Inverse block
LU Solver block
M
Magnitude FFT block
magnitude response
arbitrary <1> <2> <3> <4>
equiripple <1> <2>
multiband <1> <2> <3> <4>
of Butterworth filters <1> <2>
of Chebyshev type I filters <1> <2>
of Chebyshev type II filters <1> <2>
of elliptic filters <1> <2>
of Yule-Walker IIR Filter Design block
piecewise linear
specifying
example of
magnitudes
converting to dB
of frequency response <1> <2>
Magnitudes parameter
length of <1> <2>
Math Functions library
Math Operations library
MATLAB
Demos window <1> <2>
matrices
2-norm
diagonal <1> <2>
dimensions
defined
displaying
as images
extracting diagonal of
extracting triangle from
frame-based
format of
generated by buffering
identity <1> <2>
multiplying
multiplying within
normalizing
number of channels in
permuting
scaling
selecting elements from
summing
support for
Toeplitz
transposing
Matrices and Linear Algebra library
Matrix 1-Norm block
Matrix Concatenation block
Matrix Factorizations library
Matrix Functions library
Matrix Inverses library
Matrix Multiply block
Matrix Operations library
Matrix Product block
Matrix Scaling block
Matrix Square block
Matrix Sum block
in tutorial
Matrix Viewer block <1> <2>
maximum
Maximum block
mean
computing
Mean block <1> <2>
Median block
memory
conserving
contiguous
M-files
dspstartup <1> <2> <3>running simulations from
startupstartupsavMi (input frame size). See frame sizes
minimum
Minimum block
MMSE
mn (normalized magnitude vector)
See magnitudes
Mo (output frame size). See frame sizes
models
building
defining
multirate
simulating
modes, tasking
Modified Covariance AR Estimator block
Modified Covariance Method block
mono inputs
multiband filter designs
digital, available parameters
tabulated
using Least Squares FIR Filter Design block
using Remez FIR Filter Design block
See also filter band configurations, multiband
multichannel signals
constructing <1> <2>
deconstructing
See also signals <1> <2>
Multiphase Clock block
multiplying
by dB gain
matrices
Multi-port Selector block
multirate blocks
multirate filtering
Multirate Filters library
multirate models <1> <2>
multi-tasking mode
multitasking mode
N
See sample vectors and matrices
Normalization block
normalized frequencies
defined
See also frequencies
norms, 2-norm
N-Sample Enable block
N-Sample Switch block
n-step forward linear predictors
Nyquist frequency
defined
related to sample frequency
Nyquist rate
defined
O
(digital frequency) defined
See also frequencies
(angular frequency) defined
See also frequencies
p (passband edge frequency) See edge frequencies
p1 (lower passband edge frequency) See edge frequencies
p2 (upper passband edge frequency) See edge frequencies
s (stopband edge frequency) See edge frequencies
s1 (lower stopband edge frequency) See edge frequencies
s2 (upper stopband edge frequency) See edge frequencies
ones, outputting
online help
optimal fits
Out block, suppressing output
Output check box
output frame periods
defined
See also frame periods
output frame sizes. See frame sizes
output periods. See frame periods
output sample periods. See sample periods
Overlap-Add FFT Filter block <1> <2>
overlap-add method
overlapping buffers <1> <2>
causing unintentional rate conversions
Overlap-Save FFT Filter block <1> <2>
overlap-save method
overview of DSP Blockset
P
pages of an array
defined
exporting
pages of an array, importing
parameters
Band edge frequencies <1> <2> <3>
Buffer overlap, negative values for
continuous-time filter
definition of
discrete-time filter <1> <2>
InvariantConstantsMagnitudes <1> <2>
length of
normalized frequency <1> <2>
RTWOptionsSaveOutputSaveTimesetting
Simulink
SolverStopTimetuning <1> <2>
Weights
and Least Squares FIR Filter Design block
and Remez FIR Filter Design block
example of
for differentiator <1> <2>
length of
with T symbol
parametric estimation
Parametric Estimation library
Parks-McClellan algorithm <1> <2>
Partial Unbuffer block
partial unbuffering
passband ripple
analog filter
digital filter
performance, improving <1> <2> <3>
periodograms
periods
defined
See sample periods and frame periods
Permute Matrix block
phase angles, unwrapping
Polynomial Evaluation block
Polynomial Functions library
Polynomial Stability Test block
polyphase filter structures <1> <2> <3>
ports, connecting
power spectrum estimation
using the Burg method <1> <2> <3>
using the short-time, fast Fourier transform (ST-FFT)
using the Yule-Walker AR method
Power Spectrum Estimation library
prediction, linear
predictor algorithm
Probe block
example
Pseudoinverse block
Q
QR Solver block
Quantizer block
Quantizers library
Queue block
Quicksort algorithm
R
raised cosine filter designs
ramp signal
random signals
Random Source block
random-walk Kalman filter
rate conversion <1> <2>
blocks for
by buffering
by unbuffering
direct <1> <2>
overview
to avoid rate-mismatch errors
unintentional <1> <2>
rate types
block
model
rates
auto-promoting
See also sample periods and frame periods
Real Cepstrum block
Real-Time Workshop
and contiguous memory
and loop-rolling
generating generic real-time (GRT) code
Real-Time Workshop panel
rebuffer_delay <1> <2>rebuffering <1> <2> <3>
blocks for
causing unintentional rate conversions
delay <1> <2>
computing
procedure
with alteration of the signal <1> <2>
with preservation of the signal <1> <2>
Reciprocal Condition block
recursive least-squares (RLS) algorithm
remez <1> <2>Remez exchange algorithm <1> <2>
Remez FIR Filter Design block <1> <2> <3> <4> <5>
algorithm
and
remezRepeat block <1> <2>
resampling <1> <2> <3> <4> <5>
by inserting zeros
procedure
ripple, passband <1> <2>
RLS (recursive least-squares) algorithm
RLS Adaptive Filter block
RMS block <1> <2>
RMS, computing
root-mean-square. See RMS <1> <2>
Rp (passband ripple)
See passband ripple
Rs (stopband attenuation)
See stopband attenuation <1> <2>
RTW. See Real-Time Workshop
RTWOptions parameterrunning operations
S
sample frequency
definition
related to Nyquist frequency
See also sample periods
sample modes
sample periods
altered by buffering
altered by unbuffering
color coding
continuous-time
converting <1> <2>
See also rate conversion
defined <1> <2> <3> <4>
discrete-time
for Buffer block
for frame-based signals
for nonsource blocks
for Rebuffer block
inherited
input, defined
inspecting
using color coding
using the Simulink Probe block <1> <2>
maintaining constant <1> <2>
of source blocks
output, defined
related to frame period and frame size <1> <2>
See also frame periods and sample times
sample rates
auto-promoting
changing <1> <2>
defined <1> <2>
inherited
overview
See also sample periods
Sample time colors option
Sample time of original time series parameter
Sample time parameter
sample times
color coding
defined <1> <2> <3>
shifting with sample-time offsets
See also sample periods and frame periods
sample-based signals <1> <2>
converting to frame-based signals
creating from frame-based signals
importing <1> <2>
samples
adding <1> <2>
deleting <1> <2>
rearranging
sampling
See also sample periods and frame periods
SaveOutput parameterSaveTime parameterscalars
converting to vectors <1> <2>
creating from vectors
exporting
importing <1> <2>
Scope block
scopes
scripts
seconds
selecting
elements of a vector
Selector block
sequences
defining a discrete-time signal
settings, Simulink
Shift Register block
initial state of
Short-Time FFT block
short-time, fast Fourier transform (ST-FFT) method
Signal Attributes library
Signal From Workspace block
compared to Simulink To Workspace block
Signal Management library
Signal Operations library
Signal Processing Toolbox <1> <2> <3> <4>
documentation
signals
continuous-time
control <1> <2> <3>
discrete-time
characteristics
defined
inspecting the sample period of
terminology <1> <2>
exporting
frame-based
benefits
converting to sample-based <1> <2>
multichannel
frequency of, defined <1> <2>
generating
importing <1> <2>
sample-based
multichannel <1> <2>
Nyquist frequency, defined
Nyquist rate, defined
period of, defined
random
sample-based <1> <2>
converting to frame-based
Simulation Parameters dialog box <1> <2> <3>
simulations
accelerating <1> <2> <3>
running
from M-file
from the command line
size of generated code
stopping
Simulink
accessing
configuring for DSP
default settings
description
learning <1> <2>
libraries <1> <2>
parameters
simulinkSine Wave block <1> <2>
in tutorial
single-rate blocks
single-rate models
single-tasking mode <1> <2>
Singular Value Decomposition block
size
of a frame
See also frame sizes
of a matrix
of an array
size of a vector
defined
See also frame sizes
sliding windows
example
Solver options panel, recommended settings
Solver parametersolvers
fixed-step
variable-step
Sort block
sound
exporting <1> <2> <3>
importing <1> <2>
sources
discrete-time
sample periods of
spectral analysis
Burg method
covariance method
magnitude FFT method
modified covariance method
See also power spectrum estimation
short-time FFT method
Yule-Walker method
Spectrum Scope block <1> <2>
speed, improving <1> <2> <3>
Stack block
stack events <1> <2>
standard deviation
computing
Standard Deviation block <1> <2>
startup M-filestartupsav M-fileediting
state-space forms <1> <2>
statistics
operations <1> <2>
RMS
standard deviation
variance
Statistics library <1> <2>
stereo inputs
Stereo parameter
ST-FFT method
stopband, attenuation <1> <2>
stopping a simulation
StopTime parameterSubmatrix block
SVD Solver block
Switches and Counters library
switching
between two inputs
symbols, time and frequency
T
defined
See also sample periods and frame periods
T (tunable) icon
tasking latency
defined
example
predicting
tasking modes
technical conventions
terminology, time and frequency <1> <2>
Tf (frame period)
defined
See also frame periods
Tfi (input frame period)
defined
See also frame periods
Tfo (output frame period)
defined
See also frame periods
throughput rates, increasing
Time check box
Time Scope Blcok
time-step vector, saving to workspace
Time-Varying Direct-Form II Transpose Filter
initial conditions for
Time-Varying Direct-Form II Transpose Filter block
Time-Varying Lattice Filter block
initial conditions for
To Wave Device block <1> <2>
To Wave File block <1> <2>
Toeplitz block
tout vector, suppressingtransforms
discrete cosine
Fourier
Transforms library
transition regions <1> <2>
Transpose block
transposed direct-form II IIR filter <1> <2>
transposing
matrices
trends, removing
triangular windows
triggered blocks
Triggered Delay Line block
Triggered Shift Register block
initial state of
Triggered Signal From Workspace block
Triggered Signal To Workspace block
triggering
for N-Sample Enable block <1> <2>
for Sample and Hold block
for Triggered Shift Register block
for Triggered Signal From Workspace block
for Triggered Signal To Workspace block
Ts (sample period)
defined <1> <2>
See also sample periods
Tsi (input sample period)
defined
See also sample periods
Tso (output sample period)
defined
See also sample periods
tuning parameters <1> <2>
typographical conventions (table)
U
initial state of
unbuffering <1> <2> <3>
and rate conversion
frame-based signals
partial
to a sample-based signal
Uniform Decoder block
Uniform Encoder block <1> <2>
units of time and frequency measures
Unwrap block
unwrapping radian phase angles
Upsample block <1> <2> <3>
upsampling <1> <2> <3> <4>
by inserting zeros
See also rate conversion
utility functions
dsp_linksdsplibdspstartuprebuffer_delayV
initial conditions for <1> <2>
Variable Integer Delay block
initial conditions for <1> <2>
Variable Selector block <1> <2> <3> <4>
variable-step solver <1> <2>
variance <1> <2>
tracking
Variance block <1> <2>
Vector Scope block <1> <2> <3>
vectors
1-D <1> <2>
converting to scalars
creating
by buffering
from scalars
defined
displaying <1> <2>
exporting
importing <1> <2>
versions
displaying information about
opening
viewing data
with scopes
W
Wavelet Synthesis block <1> <2>
Weights parameter
and Least Squares FIR Filter Design block
and Remez FIR Filter Design block
example
for differentiator
for Hilbert transformer
length of
Window Function block
windows
applying
Bartlett
Blackman
Boxcar
Chebyshev <1> <2>
computing
Hamming
Hann
Kaiser <1> <2>
triangular
workspace
importing data from
suppressing output to
Workspace I/O panel
Y
yout, suppressingyulewalk <1> <2>Yule-Walker Estimator block
Yule-Walker IIR Filter Design block <1> <2> <3> <4>
characteristics of
Yule-Walker Method block
Z
Zero-Order Hold block
zero-padding <1> <2> <3>
causing unintentional rate conversions
zeros
inserting <1> <2> <3>
outputting
Counter block
Discrete Impulse block
Integer Delay block
N-Sample Enable block
Signal From Workspace block <1> <2>
padding with <1> <2>