To generate a DSB-SC signal for t∈(−0.05,0.05)t \in (-0.05, 0.05)t∈(−0.05,0.05) with a carrier frequency of 500 Hz and plot the waveform and spectrum of the information, carrier, and modulated signals, follow these steps:Step 1: Generate the Modulating Signal (m(t))
For simplicity, let the modulating signal be a sine wave:
m(t)=Am⋅sin(2πfmt)m(t) = A_m \cdot \sin(2 \pi f_m t)m(t)=Am⋅sin(2πfmt)
Where:
- AmA_mAm is the amplitude of the modulating signal,
- fmf_mfm is the frequency of the modulating signal (choose a lower frequency, for example, 50 Hz).
Step 2: Generate the Carrier Signal (c(t))
The carrier signal is:
c(t)=Ac⋅cos(2πfct)c(t) = A_c \cdot \cos(2 \pi f_c t)c(t)=Ac⋅cos(2πfct)
Where:
- fc=500 Hzf_c = 500 \, \text{Hz}fc=500Hz (the given carrier frequency).
Step 3: Generate the DSB-SC Modulated Signal (s(t))
The DSB-SC modulated signal is the product of the carrier and modulating signal:
s(t)=Ac⋅m(t)⋅cos(2πfct)s(t) = A_c \cdot m(t) \cdot \cos(2 \pi f_c t)s(t)=Ac⋅m(t)⋅cos(2πfct)Step 4: Plot the Signals
- Plot the modulating signal, carrier signal, and the modulated signal over time for t∈(−0.05,0.05)t \in (-0.05, 0.05)t∈(−0.05,0.05).
- Use Fourier transform to plot the frequency spectrum of the modulated signal.
Application Development in Mobile App Consulting:
For mobile app consulting, you can focus on industries like telecommunication, mobile solutions, and IoT, all of which benefit from DSB-SC modulation for communication systems. Mobile app developers can create apps that simulate or analyze signal modulation for educational or professional purposes.
