DSP FIRST 2e – Resources

DSP FIRST 2e 5. FIR Filters – Problems with selected Solutions ⁷⁷

5–1 Unit-step response of FIR system via convolution Solution

difference equation FIR impulse response filter coefficients

5–2 Length of Convolution Solution

flip and slide support

5–3 Impulse response of cascaded LTI systems Solution

delta filter coefficients running average filter

5–4 Difference equation and impulse response of cascaded LTI systems Solution

delta FIR

5–5 Block diagram of FIR system and output signal Solution

impulse response delta

5–6 Output from FIR Filter for Finite-Length Input Signal ♦ Impulse Response Solution

impulse LTI output

5–7 Output from FIR Filter for Complex Exponential Input Signal Solution

difference exponential output

5–8 Running Average FIR Filter ♦ Step Response Solution

average filter running

5–9 Linearity & Time-Invariance Properties Solution

frequency input LTI output

5–10 Difference Equation Block Diagram of FIR Filter Solution

block difference filter

5–11 Plot Finite-Length Signal \(x[n]\) Defined by Shifted Impulses Solution

delay Dirac shift step

5–12 Difference Equation from Block Diagram of FIR Filter Solution

block difference filter

5–13 Linearity & Time-Invariance Used to Construct Output Signal Solution

input LTI output

5–14 Output from FIR Filter for Complex Exponential Input Signal Solution

exponential filter output

5–15 Output of LTI System to \(u[n]\)

FIR difference equation unit step function running sum

5–16 Output of LTI System to Complex Exponentials

FIR difference equation unit step function running sum

5–17 Output from FIR Filter for Finite-Length Input Signal

difference FIR filter impulse response LTI

5–18 Draw Block Diagrams from FIR Difference Equation

LTI direct form transposed direct form

5–19 Determine the Duration of the Output of an FIR Filter

FIR Filter Output support convolution

5–20 Construct Output via Linearity and Time-Invariance

Linearity Time-Invariance FIR filter

5–21 Construct Output via Linearity and Time-Invariance

input LTI output unit step

5–22 Impulse response of cascade of two systems Solution

cascade difference equation

5–23 Properties of LTI systems Solution

linearity time-invariance causality

5–24 Output signal using linearity & time-invariance Solution

FIR shifted impulse causality

5–25 Difference equation and \(H(z)\) from impulse response Solution

convolution delta output signal

5–26 Difference equation and \(H(z)\) from impulse response Solution

convolution delta output signal

5–27 Determine the Output of an FIR Filter for a Given Input Solution

FIR Filter Output

5–28 Determine the Duration of the Output of an FIR Filter Solution

FIR Filter Output

5–29 Cascade Connection of LTI Systems Solution

Cascade LTI

5–30 Find Outputs of an FIR Filter for Step and Cosine Inputs Solution

FIR Filter Output

5–31 Find Outputs of an FIR Filter for Step and Cosine Inputs Solution

FIR Filter Output

5–32 Find Outputs of an FIR Filter for Step and Cosine Inputs Solution

FIR Filter Output

5–33 Using the Unit Step Sequence to Represent a Finite-Length Signal Solution

unit step finite-length

5–34 Determine the Duration of the Output of an FIR Filter Solution

FIR filter impulse response

5–35 Cascade Connection of LTI Systems Solution

cascade difference equation impulse response

5–36 Test for Linearity and Time-Invariance

Linearity Time-Invariance

5–37 Unit step response of 3-point averager Solution

finite-length pulse

5–38 Nonzero region of FIR filter output Solution

convolution filter coefficients

5–39 Impulse response & difference equation of cascaded systems Solution

convolution

5–40 FIR filtering of signal defined by its spectrum Solution

9-point averager output signal

5–41 Difference equation & block diagram from impulse response Solution

linear time-invariant causal nonlinear system

5–42 Output from convolution of impulse response & input pulse Solution

running sum FIR

5–43 Difference equation & block diagram from impulse response Solution

linear time-invariant causal nonlinear system

5–44 Output from convolution of impulse response & input pulse Solution

running sum FIR

5–45 Difference equation & block diagram from impulse response Solution

linear time-invariant causal nonlinear system

5–46 Output from convolution of impulse response & input pulse Solution

running sum FIR

5–47 Linearity & Time-Invariance Used to Construct Output Signal Solution

input LTI output

5–48 Linearity & Time-Invariance Used to Construct Output Signal Solution

input LTI output

5–49 Output from FIR Filter for Finite-Length Input Signal Solution

filter input LTI output

5–50 Output from FIR Filter for Complex Exponential Input Signal Solution

amplitude difference exponential phase

5–51 Output from FIR Filter for Finite-Length Input Signal Solution

difference filter output

5–52 Impulse Response of FIR Filter ♦ Complex Exponential Response Solution

difference exponential filter impulse

5–53 Output of LTI System to Finite Length Complex Exponential

FIR difference equation

5–54 Output from FIR Filter for Finite-Length Input Signal Solution

difference equation convolution LTI

5–55 Construct Output via Linearity and Time-Invariance Solution

linearity time-invariance FIR filter causal

5–56 Matching Output Signal to \(h[n]\) or Difference Equation Solution

impulse response conv

5–57 Output from FIR Filter for Complex Exponential Input Signal Solution

difference exponential filter output

5–58 Linearity & Time-Invariance Used to Construct Output Signal Solution

LTI ramp step

5–59 Output from FIR Filter for Complex Exponential Input Signal Solution

amplitude difference exponential filter phase

5–60 Running Average FIR Filter ♦ Step Response Solution

averager filter running step

5–61 Output from FIR Filter for Finite-Length Input Signal Solution

difference filter LTI output

5–62 Output from FIR Filter for Finite-Length Input Signal Solution

filter input LTI output

5–63 Output from FIR Filter for Finite-Length Input Signal Solution

filter input LTI output

5–64 Linearity & Time-Invariance Used to Construct Output Signal Solution

input LTI output

5–65 Output from FIR Filter for Complex Exponential Input Signal Solution

amplitude difference exponential filter phase

5–66 Linearity & Time-Invariance Used to Construct Output Signal Solution

Dirac LTI output

5–67 Output from FIR Filter for Finite-Length Input Signal ♦ Impulse Response Solution

difference filter impulse

5–68 Output of LTI System to \(u[n]\) Solution

FIR difference equation unit step function running sum

5–69 Determine the Duration of the Output of an FIR Filter Solution

FIR filter length

5–70 Construct Output via Linearity and Time-Invariance Solution

linearity time-invariance FIR filter causal

5–71 Find Output of FIR Filter Given Coefficients Solution

MATLAB shifted impulse

5–72 Construct Output via Linearity and Time-Invariance Solution

input LTI output impulse signal

5–73 Output from FIR Filter for Finite-Length Input Signal Solution

difference equation convolution LTI

5–74 Cascade of Two LTI Systems Solution

blurring filter impulse response difference equation

5.1–75 Running Average FIR Filter ♦ Time Response Solution

averager running step

5.6–76 Output from FIR Filter for Finite-Length Input Signal Solution

filter impulse output

5.8–77 Linearity & Time-Invariance Used to Construct Output Signal Solution

input LTI output