DSP using MATLAB 示例Example2.4

n = [0:10]; x = stepseq(0,0,10) - stepseq(10,0,10);
[xe,xo,m] = evenodd(x,n);

set(gcf,‘Color‘,[1,1,1])                  % 改变坐标外围背景颜色
stem(n,x); title(‘Rectangular Pulse‘);
xlabel(‘n‘); ylabel(‘x(n)‘) ; axis([-10,10,0,1.2])
grid on

figure
set(gcf,‘Color‘,[1,1,1])
stem(m,xe); title(‘Even Part‘);
xlabel(‘n‘); ylabel(‘xe(n)‘); axis([-10,10,0,1.2])
grid on

figure
set(gcf,‘Color‘,‘white‘)
stem(m,xo); title(‘Odd Part‘);
xlabel(‘n‘); ylabel(‘xe(n)‘); axis([-10,10,-0.6,0.6])
grid on

结果:

  

时间: 2024-10-25 00:36:34

DSP using MATLAB 示例Example2.4的相关文章

DSP using MATlAB 示例Example2.10

上代码 % noise sequence 1 x = [3, 11, 7, 0, -1, 4, 2]; nx = [-3:3]; % given signal x(n) [y,ny] = sigshift(x,nx,2); % obtain x(n-2) set(gcf,'Color','white') subplot(2,1,1);stem(nx,x); title('sequence x(n)'); xlabel('n');ylabel('x(n)'); grid on subplot(2,

DSP using MATLAB 示例Example2.12

代码: b = [1]; a = [1, -0.9]; n = [-5:50]; h = impz(b,a,n); set(gcf,'Color','white'); %subplot(2,1,1); stem(n,h); title('Impulse Response'); xlabel('n'); ylabel('h(n)'); grid on; x = stepseq(0, -5, 50) - stepseq(10, -5, 50) y = filter(b, a, x); figure;

DSP using MATLAB 示例Example2.3

n = [-10:1:10]; alpha = -0.1+0.3j; % x = exp(alpha*n); % subplot(2,1,1); set(gcf,'Color',[1,1,1]) % 改变坐标外围背景颜色 stem(n,real(x)); title('real part'); xlabel('n'); grid on figure set(gcf,'Color','white') % 新生成一张图 stem(n,imag(x)); title('imaginary part')

DSP using MATLAB 示例Example2.11

上代码: b = [1]; a = [1, -1, 0.9]; n = [-20:120]; h = impz(b,a,n); set(gcf,'Color','white'); %subplot(2,1,1); stem(n,h); title('Impulse Response'); xlabel('n'); ylabel('h(n)'); grid on; x = stepseq(0,-20, 120); s = filter(b,a,x); figure; set(gcf,'Color'

DSP using Matlab 示例Example2.2

a. n = -2:10; x = [1:7,6:-1:1]; % generate x(n) [x11,n11] = sigshift(x,n,5); [x12,n12] = sigshift(x,n,-4); [x1,n1] = sigadd(2 * x11, n11, -3 * x12, n12); set(gcf,'Color',[1,1,1]) % 改变坐标外围背景颜色 stem(n,x); title('Sequence x(n)') xlabel('n');ylabel('x(n)

DSP using MATLAB 示例Example3.21

代码: % Discrete-time Signal x1(n) % Ts = 0.0002; n = -25:1:25; nTs = n*Ts; Fs = 1/Ts; x = exp(-1000*abs(nTs)); Ts = 0.001; n = -5:1:5; nTs = n*Ts; Fs = 1/Ts; x = exp(-1000*abs(nTs)); % Analog Signal Dt = 0.00005; t = -0.005:Dt:0.005; xa = x * sinc(Fs*

DSP using MATLAB示例Example3.18

代码: % Analog Signal Dt = 0.00005; t = -0.005:Dt:0.005; xa = exp(-1000*abs(t)); % Continuous-time Fourier Transform Wmax = 2*pi*2000; K = 500; k = 0:1:K; % index array k for frequencies W = k*Wmax/K; % freqency between 0 and +pi, [0,pi] axis divided i

DSP using MATLAB 示例 Example3.19

代码: % Analog Signal Dt = 0.00005; t = -0.005:Dt:0.005; xa = exp(-1000*abs(t)); % Discrete-time Signal Ts = 0.0002; n = -25:1:25; x = exp(-1000*abs(n*Ts)); % Discrete-time Fourier Transform %Wmax = 2*pi*2000; K = 500; k = 0:1:K; w = pi*k/K; % index ar

DSP using MATLAB 示例 Example3.15

上代码: subplot(1,1,1); b = 1; a = [1, -0.8]; n = [0:100]; x = cos(0.05*pi*n); y = filter(b,a,x); figure('NumberTitle', 'off', 'Name', 'Input and Output sequence'); set(gcf,'Color','white'); subplot(2,1,1); stem(n,x); title('Input sequence'); xlabel('n'