Hello Dali,
To properly decimate a digital data stream, it is important to consider the anti-aliasing filter requirements. In your case, since you have a second-order delta sigma modulator, it is likely that the output bitstream contains high-frequency noise that needs to be filtered out before decimation.
To achieve this, you can design and apply a low-pass filter to the bitstream before passing it to the decimation filter. This low-pass filter should have a cutoff frequency that is less than half of the desired output sample rate after decimation. You can use the "fir1" function in MATLAB to design the low-pass filter.
Here is a demonstration:
% Parameters
Fs = 3.2e6; % Sampling frequency (e.g., 3.2 MHz)
t = 0:1/Fs:0.01-1/Fs; % Time vector for 10 ms
f = 1e3; % Frequency of the sine wave (e.g., 1 kHz)
% Simulate a sine wave as an example input
inputSignal = 0.5*sin(2*pi*f*t) + 1.5; % Sine wave offset to match 0~3V range
% Simulate ΔΣ modulator output (simplified)
% Here, I simply add noise to simulate a high-frequency bitstream
% In a real scenario, this would be the output from your ΔΣ modulator
noiseSignal = inputSignal + 0.2*randn(size(inputSignal)); % Adding Gaussian noise
% Create a binary-like bitstream to mimic ΔΣ modulated output
threshold = 1.5; % Threshold for binary conversion
bitstream = noiseSignal > threshold; % Convert to binary (0 or 1)
bitstream = bitstream * 3.3; % Scale to 0~3.3V range
% Design a low-pass filter using fir1
N = 50; % Filter order
Fc = 2000; % Cutoff frequency (Hz)
Wn = Fc/(Fs/2); % Normalized cutoff frequency (0 < Wn < 1)
b = fir1(N, Wn); % FIR filter coefficients
% Filter the noisy signal
filtered_signal = filter(b, 1, noiseSignal); % Filter the noisy signal
% Decimation
decimationFactor = 32; % Decimation factor
decimatedSignal = decimate(filtered_signal, decimationFactor, 'fir');
% Plotting
figure;
% Original Input Signal
subplot(5,1,1);
plot(t, inputSignal);
title('Original Input Signal');
xlabel('Time (s)');
ylabel('Amplitude (V)');
% Noisy Input Signal
subplot(5,1,2);
plot(t, noiseSignal);
title('Noisy Input Signal');
xlabel('Time (s)');
ylabel('Amplitude (V)');
% Simulated ΔΣ Modulator Output Bitstream
subplot(5,1,3);
stairs(t, bitstream); % Use 'stairs' for a more accurate digital signal representation
title('Simulated ΔΣ Modulator Output Bitstream');
xlabel('Time (s)');
ylabel('Amplitude (V)');
% Filtered Noisy Signal
subplot(5,1,4);
plot(t, filtered_signal);
title('Filtered Noisy Signal');
xlabel('Time (s)');
ylabel('Amplitude (V)');
% Decimated Signal
t_decimated = downsample(t, decimationFactor); % Downsample the time vector for plotting
subplot(5,1,5);
plot(t_decimated, decimatedSignal);
title('Decimated Signal');
xlabel('Time (s)');
ylabel('Amplitude (V)');
For more information about the "fir1" function, please refer to the documentation:
I hope this helps!
