From b1f5c3f8d6671b4331cef1dcebdf63b7a43a3a2b Mon Sep 17 00:00:00 2001 From: priyanka Date: Wed, 24 Jun 2015 15:03:17 +0530 Subject: initial commit / add all books --- 716/CH9/EX9.1.III/9_11_ShortQnA_9_1.sce | 21 +++++++++++++++++ 716/CH9/EX9.1/Solved_Ex9_1.sce | 41 +++++++++++++++++++++++++++++++++ 716/CH9/EX9.2.III/9_11_ShortQnA_9_2.sce | 21 +++++++++++++++++ 716/CH9/EX9.2.V/9_13_ExerciseV9_2.sce | 21 +++++++++++++++++ 716/CH9/EX9.2.m/MatLab_Prog9_2.sce | 24 +++++++++++++++++++ 716/CH9/EX9.2/Solved_Ex9_2.sce | 16 +++++++++++++ 716/CH9/EX9.3.V/9_13_ExerciseV9_3.sce | 21 +++++++++++++++++ 716/CH9/EX9.3/Solved_Ex9_3.sce | 21 +++++++++++++++++ 716/CH9/EX9.4.V/9_13_ExerciseV9_4.sce | 21 +++++++++++++++++ 716/CH9/EX9.5.m/MatLab_Prog9_5.sce | 21 +++++++++++++++++ 716/CH9/EX9.5/Solved_Ex9_5.sce | 16 +++++++++++++ 716/CH9/EX9.6/Solved_Ex9_6.sce | 25 ++++++++++++++++++++ 716/CH9/EX9.7/Solved_Ex9_7.sce | 25 ++++++++++++++++++++ 13 files changed, 294 insertions(+) create mode 100755 716/CH9/EX9.1.III/9_11_ShortQnA_9_1.sce create mode 100755 716/CH9/EX9.1/Solved_Ex9_1.sce create mode 100755 716/CH9/EX9.2.III/9_11_ShortQnA_9_2.sce create mode 100755 716/CH9/EX9.2.V/9_13_ExerciseV9_2.sce create mode 100755 716/CH9/EX9.2.m/MatLab_Prog9_2.sce create mode 100755 716/CH9/EX9.2/Solved_Ex9_2.sce create mode 100755 716/CH9/EX9.3.V/9_13_ExerciseV9_3.sce create mode 100755 716/CH9/EX9.3/Solved_Ex9_3.sce create mode 100755 716/CH9/EX9.4.V/9_13_ExerciseV9_4.sce create mode 100755 716/CH9/EX9.5.m/MatLab_Prog9_5.sce create mode 100755 716/CH9/EX9.5/Solved_Ex9_5.sce create mode 100755 716/CH9/EX9.6/Solved_Ex9_6.sce create mode 100755 716/CH9/EX9.7/Solved_Ex9_7.sce (limited to '716/CH9') diff --git a/716/CH9/EX9.1.III/9_11_ShortQnA_9_1.sce b/716/CH9/EX9.1.III/9_11_ShortQnA_9_1.sce new file mode 100755 index 000000000..d81d75e57 --- /dev/null +++ b/716/CH9/EX9.1.III/9_11_ShortQnA_9_1.sce @@ -0,0 +1,21 @@ +//Perform DFT of x(n)=(1 1 -2 -2) and sketch magnitude and phase spectrum +clc; +clear; +N=4; +xn=[1 1 -2 -2]; +for k=0:1:N-1 + Xk(k+1)=0; + for n=0:1:N-1 + Xk(k+1)=Xk(k+1)+xn(n+1)*exp(-%i*2*%pi*k*n/N); + end +end +wk=0:1:N-1; +disp(Xk,'4 point DFT of x(n)=>'); +disp(abs(Xk),'magnitude of 4 point DFT x(n)=>'); +disp(atan(imag(Xk),real(Xk)),'phase of 4 point DFT x(n)=>'); +subplot(1,2,1) +plot2d3(wk,abs(Xk),2); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(wk,atan(imag(Xk),real(Xk)),2); +xtitle('Phase Spectrum','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.1/Solved_Ex9_1.sce b/716/CH9/EX9.1/Solved_Ex9_1.sce new file mode 100755 index 000000000..b35e4dbbc --- /dev/null +++ b/716/CH9/EX9.1/Solved_Ex9_1.sce @@ -0,0 +1,41 @@ +//compute 4 point DFT & 8 point DFT and from magnitude and phase spectrums show that DFT coefficients are the samples of Fourier Transform +clc; +clear; +disp('Given signal=> x(n)=1/3.*(n1>=0 & n1<=2)'); +n1=0:1:3;//for four point DFT +x1=1/3.*(n1>=0 & n1<=2) +X1=dft(x1,-1); +disp(X1,'four point DFT of x(n)=>'); +disp(abs(X1),'magnitude of four point DFT x(n)=>'); +disp(atan(imag(X1),real(X1)),'phase of four point DFT x(n)=>'); +subplot(1,2,1) +plot2d3(n1,abs(X1),2); +xtitle('Magnitude Spectrum for 4 point DFT','k','|X(k)|'); +subplot(1,2,2) +plot2d3(n1,atan(imag(X1),real(X1)),2); +xtitle('Phase Spectrum for 4 point DFT','k','angle(X(k))'); + +n2=0:1:7;//for Eight point DFT +x2=1/3.*(n2>=0 & n2<=2) +X2=dft(x2,-1); +disp(X2,'eight point DFT of x(n)=>'); +disp(abs(X2),'magnitude of eight point DFT x(n)=>'); +disp(atan(imag(X2),real(X2)),'phase of four point DFT x(n)=>'); +xset('window',1); +subplot(1,2,1) +plot2d3(n2,abs(X2),2); +xtitle('Magnitude Spectrum for 8 point DFT','k','|X(k)|'); +subplot(1,2,2) +plot2d3(n2,atan(imag(X2),real(X2)),2); +xtitle('Phase Spectrum for 8 point DFT','k','angle(X(k))'); + +n3=0:1:15;//for four point DFT +x3=1/3.*(n3>=0 & n3<=2) +X3=dft(x3,-1); +xset('window',2); +subplot(1,2,1) +plot2d3(n3,abs(X3),2); +xtitle('Magnitude Spectrum for 8 point DFT','k','|X(k)|'); +subplot(1,2,2) +plot2d3(n3,atan(imag(X3),real(X3)),2); +xtitle('Phase Spectrum for 16 point DFT','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.2.III/9_11_ShortQnA_9_2.sce b/716/CH9/EX9.2.III/9_11_ShortQnA_9_2.sce new file mode 100755 index 000000000..3b66e77ae --- /dev/null +++ b/716/CH9/EX9.2.III/9_11_ShortQnA_9_2.sce @@ -0,0 +1,21 @@ +//Perform 4 point DFT of x(n)=(1 1 0 0) and sketch magnitude and phase spectrum +clc; +clear; +N=4; +xn=[1 1 0 0]; +for k=0:1:N-1 + Xk(k+1)=0; + for n=0:1:N-1 + Xk(k+1)=Xk(k+1)+xn(n+1)*exp(-%i*2*%pi*k*n/N); + end +end +wk=0:1:N-1; +disp(Xk,'4 point DFT of x(n)=>'); +disp(abs(Xk),'magnitude of 4 point DFT x(n)=>'); +disp(atan(imag(Xk),real(Xk)),'phase of 4 point DFT x(n)=>'); +subplot(1,2,1) +plot2d3(wk,abs(Xk),2); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(wk,atan(imag(Xk),real(Xk)),2); +xtitle('Phase Spectrum','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.2.V/9_13_ExerciseV9_2.sce b/716/CH9/EX9.2.V/9_13_ExerciseV9_2.sce new file mode 100755 index 000000000..61584df58 --- /dev/null +++ b/716/CH9/EX9.2.V/9_13_ExerciseV9_2.sce @@ -0,0 +1,21 @@ +//Perform 4 point DFT of x(n)=(0 -1 2 1) and sketch magnitude and phase spectrum +clc; +clear; +N=4; +xn=[0 -1 2 1]; +for k=0:1:N-1 + Xk(k+1)=0; + for n=0:1:N-1 + Xk(k+1)=Xk(k+1)+xn(n+1)*exp(-%i*2*%pi*k*n/N); + end +end +wk=0:1:N-1; +disp(Xk,'4 point DFT of x(n)=>'); +disp(abs(Xk),'magnitude of 4 point DFT x(n)=>'); +disp(atan(imag(Xk),real(Xk)),'phase of 4 point DFT x(n)=>'); +subplot(1,2,1) +plot2d3(wk,abs(Xk),2); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(wk,atan(imag(Xk),real(Xk)),2); +xtitle('Phase Spectrum','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.2.m/MatLab_Prog9_2.sce b/716/CH9/EX9.2.m/MatLab_Prog9_2.sce new file mode 100755 index 000000000..93321c76e --- /dev/null +++ b/716/CH9/EX9.2.m/MatLab_Prog9_2.sce @@ -0,0 +1,24 @@ +//Perform 16 point DFT of x(n)=(1/3 1/3 1/3) and sketch magnitude and phase spectrum +clc; +clear; +N=16; +xn=zeros(1,16); +xn(1)=1/3; +xn(2)=1/3; +xn(3)=1/3; +for k=0:1:N-1 + Xk(k+1)=0; + for n=0:1:N-1 + Xk(k+1)=Xk(k+1)+xn(n+1)*exp(-%i*2*%pi*k*n/N); + end +end +wk=0:1:N-1; +disp(Xk,'16 point DFT of x(n)=>'); +disp(abs(Xk),'magnitude of 16 point DFT x(n)=>'); +disp(atan(imag(Xk),real(Xk)),'phase of 16 point DFT x(n)=>'); +subplot(1,2,1) +plot2d3(wk,abs(Xk),2); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(wk,atan(imag(Xk),real(Xk)),2); +xtitle('Phase Spectrum','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.2/Solved_Ex9_2.sce b/716/CH9/EX9.2/Solved_Ex9_2.sce new file mode 100755 index 000000000..588f06e7c --- /dev/null +++ b/716/CH9/EX9.2/Solved_Ex9_2.sce @@ -0,0 +1,16 @@ +//compute 4 point DFT of signal x(n)={0,1,2,3} +clc; +clear; +n=0:1:3;//for four point DFT +x=[0 1 2 3]; +disp(x,'Given signal=> x(n)='); +X=dft(x,-1); +disp(X,'four point DFT of x(n)=>'); +disp(abs(X),'magnitude of four point DFT x(n)=>'); +disp(atan(imag(X),real(X)),'phase of four point DFT x(n)=>'); +subplot(1,2,1) +plot2d3(n,abs(X),2); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(n,atan(imag(X),real(X)),2); +xtitle('Phase Spectrum','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.3.V/9_13_ExerciseV9_3.sce b/716/CH9/EX9.3.V/9_13_ExerciseV9_3.sce new file mode 100755 index 000000000..492d4b7ee --- /dev/null +++ b/716/CH9/EX9.3.V/9_13_ExerciseV9_3.sce @@ -0,0 +1,21 @@ +//Perform DFT of x(n)=(1 1 1 2 2) and sketch magnitude and phase spectrum +clc; +clear; +N=5; +xn=[1 1 1 2 2]; +for k=0:1:N-1 + Xk(k+1)=0; + for n=0:1:N-1 + Xk(k+1)=Xk(k+1)+xn(n+1)*exp(-%i*2*%pi*k*n/N); + end +end +wk=0:1:N-1; +disp(Xk,'4 point DFT of x(n)=>'); +disp(abs(Xk),'magnitude of 4 point DFT x(n)=>'); +disp(atan(imag(Xk),real(Xk)),'phase of 4 point DFT x(n)=>'); +subplot(1,2,1) +plot2d3(wk,abs(Xk),2); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(wk,atan(imag(Xk),real(Xk)),2); +xtitle('Phase Spectrum','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.3/Solved_Ex9_3.sce b/716/CH9/EX9.3/Solved_Ex9_3.sce new file mode 100755 index 000000000..9a9e9de57 --- /dev/null +++ b/716/CH9/EX9.3/Solved_Ex9_3.sce @@ -0,0 +1,21 @@ +//compute circular convolution of x1(n)={2 1 2 1} & x2(n)={1 2 3 4} +clc; +clear; +n=0:1:3;//for four point DFT +x1=[1 2 3 4]; +disp(x1,'Given signal=> x1(n)='); +X1=dft(x1,-1); +disp(X1,'four point DFT of x(n)=>'); +disp(abs(X1),'magnitude of four point DFT x(n)=>'); +disp(atan(imag(X1),real(X1)),'phase of four point DFT x(n)=>'); + +x2=[2 1 2 1]; +disp(x2,'Given signal=> x1(n)='); +X2=dft(x2,-1); +disp(X2,'four point DFT of x(n)=>'); +disp(abs(X2),'magnitude of four point DFT x(n)=>'); +disp(atan(imag(X2),real(X2)),'phase of four point DFT x(n)=>'); + +X3=X1.*X2; +x3=dft(X3,1); +disp(x3,'by circular convolution x3(n)=>'); \ No newline at end of file diff --git a/716/CH9/EX9.4.V/9_13_ExerciseV9_4.sce b/716/CH9/EX9.4.V/9_13_ExerciseV9_4.sce new file mode 100755 index 000000000..b03bac3dd --- /dev/null +++ b/716/CH9/EX9.4.V/9_13_ExerciseV9_4.sce @@ -0,0 +1,21 @@ +//compute circular convolution of x1(n)={-1 2 -2 1} & x2(n)={1 -2 -1 2} +clc; +clear; +n=0:1:3;//for four point DFT +x1=[-1 2 -2 1]; +disp(x1,'Given signal=> x1(n)='); +X1=dft(x1,-1); +disp(X1,'four point DFT of x(n)=>'); +disp(abs(X1),'magnitude of four point DFT x(n)=>'); +disp(atan(imag(X1),real(X1)),'phase of four point DFT x(n)=>'); + +x2=[1 -2 -1 2]; +disp(x2,'Given signal=> x1(n)='); +X2=dft(x2,-1); +disp(X2,'four point DFT of x(n)=>'); +disp(abs(X2),'magnitude of four point DFT x(n)=>'); +disp(atan(imag(X2),real(X2)),'phase of four point DFT x(n)=>'); + +X3=X1.*X2; +x3=dft(X3,1); +disp(x3,'by circular convolution x3(n)=>'); \ No newline at end of file diff --git a/716/CH9/EX9.5.m/MatLab_Prog9_5.sce b/716/CH9/EX9.5.m/MatLab_Prog9_5.sce new file mode 100755 index 000000000..2c20ecc8d --- /dev/null +++ b/716/CH9/EX9.5.m/MatLab_Prog9_5.sce @@ -0,0 +1,21 @@ +//Perform 4 point DFT of x(n)=(1 1 2 3) using FFT and sketch magnitude and phase spectrum +clc; +clear; +N=4; +xn=[1 1 2 3] +Xk=fft(xn); +wk=0:1:N-1; +disp(Xk,'16 point DFT of x(n)=>'); +disp(abs(Xk),'magnitude of 16 point DFT x(n)=>'); +disp(atan(imag(Xk),real(Xk)),'phase of 16 point DFT x(n)=>'); +plot2d3(wk,xn,2); +isoview(0,5,0,3); +xset('window',1); +subplot(1,2,1) +plot2d3(wk,abs(Xk),2); +isoview(0,5,0,5); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(wk,atan(imag(Xk),real(Xk)),2); +isoview(0,5,-5,5); +xtitle('Phase Spectrum','k','angle(X(k))'); \ No newline at end of file diff --git a/716/CH9/EX9.5/Solved_Ex9_5.sce b/716/CH9/EX9.5/Solved_Ex9_5.sce new file mode 100755 index 000000000..6b6df0969 --- /dev/null +++ b/716/CH9/EX9.5/Solved_Ex9_5.sce @@ -0,0 +1,16 @@ +//compute 8 point DFT of x(n)={2 2 2 2 1 1 1 1} +clc; +clear; +n=0:1:7;//for 8 point DFT +x=[2 2 2 2 1 1 1 1]; +disp(x,'Given signal=> x(n)='); +X=fft(x); +disp(X,'8 point FFT of x(n)=>'); +disp(abs(X),'magnitude of 8 point FFT x(n)=>'); +disp(atan(imag(X),real(X)),'phase of 8 point FFT x(n)=>'); +subplot(1,2,1) +plot2d3(n,abs(X),2); +xtitle('Magnitude Spectrum','k','|X(k)|'); +subplot(1,2,2) +plot2d3(n,atan(imag(X),real(X)),2); +xtitle('Phase Spectrum','k','angle(X(k))'); diff --git a/716/CH9/EX9.6/Solved_Ex9_6.sce b/716/CH9/EX9.6/Solved_Ex9_6.sce new file mode 100755 index 000000000..bbf6ef324 --- /dev/null +++ b/716/CH9/EX9.6/Solved_Ex9_6.sce @@ -0,0 +1,25 @@ +//Determine the Response of LTI system if input x(n)={1 1 1} and impulse Response h(n)={-1 -1} +clc; +clear; +x=[1 1 1]; +disp(x,'Input signal=> x(n)='); +h=[-1 -1]; +disp(h,'Impulse Response=> h(n)='); +k=length(x)+length(h)-1; +for n=length(x)+1:1:k + x(n)=0;//appending 0s +end +for n=length(h)+1:1:k + h(n)=0;//appending 0s +end +n=0:1:k; + +X=fft(x); +disp(X,'4 point FFT of x(n)=>'); + +H=fft(h); +disp(X,'4 point FFT of h(n)=>'); + +Y=X.*H; +y=ifft(Y); +disp(y,'Response to input,x(n)=> y(n)='); \ No newline at end of file diff --git a/716/CH9/EX9.7/Solved_Ex9_7.sce b/716/CH9/EX9.7/Solved_Ex9_7.sce new file mode 100755 index 000000000..40180ea48 --- /dev/null +++ b/716/CH9/EX9.7/Solved_Ex9_7.sce @@ -0,0 +1,25 @@ +//Determine the Response of LTI system if input x(n)={-1 1 2 1 -1} and impulse Response h(n)={-1 1 -1 1} +clc; +clear; +x=[-1 1 2 1 -1]; +disp(x,'Input signal=> x(n)='); +h=[-1 1 -1 1]; +disp(h,'Impulse Response=> h(n)='); +k=length(x)+length(h)-1; +for n=length(x)+1:1:k + x(n)=0;//appending 0s +end +for n=length(h)+1:1:k + h(n)=0;//appending 0s +end +n=0:1:k; + +X=fft(x); +disp(X,'4 point FFT of x(n)=>'); + +H=fft(h); +disp(X,'4 point FFT of h(n)=>'); + +Y=X.*H; +y=ifft(Y); +disp(y,'Response to input,x(n)=> y(n)='); \ No newline at end of file -- cgit