Full Carrier DSB-SC (AM) Signal For a full carrier AM (DSB-FC) signal: Carrier Power: \( P_c = \frac{A_c^2}{2R} \) Total Sideband Power: \( P_{SB} = \frac{m^2}{2} P_c \) Therefore, the ratio of total sideband power to carrier power is: \( \frac{P_{SB}}{P_c} = \frac{m^2}{2} \) If the modulation index doubles: \( m' = 2m \) The new ratio becomes: \( \frac{(2m)^2}{2} = \frac{4m^2}{2} = 4\left(\frac{m^2}{2}\right) \) Hence, the ratio of total sideband power to carrier power increases by a factor of 4 . Answer: 4

  Solution Let S = X 1 + X 2 . Since X 3 is independent of S, P(X 1 + X 2 < X 3 ) = E[P(X 3 > S | S)]. Because X 3 ~ U(0, 1), P(X 3 > S) = 1 − S,  for 0 ≤ S ≤ 1 0,  for S > 1 The sum S = X 1 + X 2 has the triangular density f S (s) = s,  for 0 ≤ s ≤ 1 f S (s) = 2 − s,  for 1 ≤ s ≤ 2 Hence, P(X 1 + X 2 < X 3 ) = ∫ 0 1 (1 − s)s ds = ∫ 0 1 (s − s²) ds = [s²/2 − s³/3] 0 1 = 1/2 − 1/3 = 1/6 . Final Answer P(X 1 + X 2 < X 3 ) = 1/6

IF Choice Trade-off Simulator IF Trade-off Simulator Adjust the Intermediate Frequency (IF) to see how it affects Selectivity, Image Rejection, and Tracking (based on MCQ 61). Signal Frequency ($f_s$): 1000 kHz Intermediate Frequency ($f_{IF}$): 455 kHz Image Frequency ($f_i = f_s + 2f_{IF}$) 1910 kHz Image Separation 910 kHz Q-Factor (Stability) 2.2 Analysis based on your MCQ: Online Signal Processing Simulations Main Page >

PAPR Simulator: OFDM vs. DFT-s-OFDM OFDM vs. DFT-s-OFDM Simulator Analyze Peak-to-Average Power Ratio (PAPR) for 5G/LTE Uplink Design Modulation Order (M-QAM) 4-QAM (QPSK) 16-QAM 64-QAM 256-QAM Subcarriers (N) 64 carriers Symbol Smoothing Over-sample (4x) Run Simulation Why the difference? In OFDM , symbols are independent on each carrier. Summing them causes random spikes. In DFT-s-OFDM , the DFT "spreads" each data symbol across all carriers, acting like a single-carrier signal. ...

Reed-Solomon RS(7,3) Interactive Simulator Reed–Solomon Interactive Simulator GF(2³) Engine | RS(7,3) Code | 2-Symbol Error Correction 1. Source Bitstream (Input 9 bits) Reset Channel Each 3 bits form 1 symbol in GF(2³). Total 3 data symbols. 2. Wireless Channel (Flip bits to test correction) Click any bit below to simulate noise in the air. STATUS: Clean Signal Errors: 0 symbols 3. Mathematical Decoder Syndromes ($S_1 \dots S_4$): 0, 0, 0, 0 Detected Error Positions: None 4. Recovered Data 101011000 ✓ Ma...

Spectral Efficiency Lab Determine if your channel bandwidth supports your chosen modulation scheme. Bit Rate ($R_b$) in kbps Modulation Scheme BPSK / ASK (Binary) QPSK / 4-QAM (M=4) 8-PSK (M=8) 16-QAM (M=16) 64-QAM (M=64) Use Nyquist Min. BW ($B = R_s$) Default: Null-to-Null BW ($B = 2R_s$) Current Efficiency (η): 0.5 b/s/Hz Required Bandwidth for this setup: 20.00 kHz Signal Processing Knowledge Check Which modulation technique is most susceptible to power-line noi...

Why BPSK is 3dB Better Than BFSK? In digital communications, we are always fighting noise. The goal is to send bits (0 and 1) using the least amount of energy possible. If you compare **Binary Phase Shift Keying (BPSK)** and **Binary Frequency Shift Keying (BFSK)**, BPSK is the clear winner. Here is the mathematical "why." 1. BPSK (Antipodal) BPSK uses a single carrier but flips the phase. The symbols are "opposites." $d_{BPSK} = 2\sqrt{E_b}$ Distance is the full diameter of the circle. 2. BFSK (Orthogonal) BFSK uses two different frequencies. These act like two perpendicular dimensions. ...

Rigorous MSK/GMSK Visualizer BPSK vs MSK vs GMSK Simulation Bits: Mode: BPSK MSK GMSK BT: Amp Saturation: Simulate Phase Trajectory (Degrees) RF Waveform Spectrum (dB) Technical Analysis: Baseband to Passband Pipeline This simulator treats MSK and GMSK as Continuous Phase Modulation (CPM) systems, where information is encoded in the accumulation of phase rather than absolute state jumps. 1. The Pulse Shaping (NRZ to Frequency) Digital bits are mapped to NRZ (+1/-1) . In MSK/GMSK, these are treated as Frequency Commands . In GMSK, these pulses are convolved with a Gaussian filter: h(t) = (1/&sqrt;2πσT) exp(-t 2 /2σ 2 T 2 ) 2. Phase Accumulation (The Integral) The phase φ(t) is the integral of the shaped frequency pulses. For Minimum Shift Keying, the modulation index is exactly 0.5, ensuring a 90° shift per bit. BPSK Phase jumps instantly between 0 ...