MavamQ
Member
Here's what ChatGPT syas,
"
The question ask of ChatGPT: Show me two 50Ω transmitters feeding a two input lossless combiner, with 50Ω on the output. What is the power on the output.
Let’s do it rigorously with 50 Ω systems and actual voltages, so there’s no ambiguity.
P=Vrms2RP = \frac{V_{\text{rms}}^2}{R}P=RVrms2
So each 1 W source has:
Vrms=1×50≈7.07 VV_{\text{rms}} = \sqrt{1 \times 50} \approx 7.07 \text{ V}Vrms=1×50≈7.07 V
It transforms impedances so power combines correctly.
1 W+1 W=2 W1\,\text{W} + 1\,\text{W} = 2\,\text{W}1W+1W=2W
Since the combiner is lossless:
Pout=2 WP_{\text{out}} = 2\,\text{W}Pout=2W
Vout=2×50=10 V rmsV_{\text{out}} = \sqrt{2 \times 50} = 10 \text{ V rms}Vout=2×50=10 V rms
So:
(7.07+7.07)2/50=4 W(7.07 + 7.07)^2 / 50 = 4\,\text{W}(7.07+7.07)2/50=4W
But that assumes:
Pout≤∑PinP_{\text{out}} \le \sum P_{\text{in}}Pout≤∑Pin
So:
"
The question ask of ChatGPT: Show me two 50Ω transmitters feeding a two input lossless combiner, with 50Ω on the output. What is the power on the output.
Let’s do it rigorously with 50 Ω systems and actual voltages, so there’s no ambiguity.
System you asked for
- Two independent 50 Ω transmitters, each delivering 1 W
- Feeding a lossless 2-way combiner
- Output terminated in 50 Ω
- Signals are same frequency and in phase
Step 1 — Voltage of each transmitter
For a 50 Ω system:P=Vrms2RP = \frac{V_{\text{rms}}^2}{R}P=RVrms2
So each 1 W source has:
Vrms=1×50≈7.07 VV_{\text{rms}} = \sqrt{1 \times 50} \approx 7.07 \text{ V}Vrms=1×50≈7.07 V
Step 2 — What a lossless combiner actually does
A proper lossless combiner (e.g., an idealized Wilkinson combiner) ensures:- Each source still “sees” 50 Ω
- Power from both sources is delivered to the output
- No reflections, no dissipation (ideal case)
It transforms impedances so power combines correctly.
Step 3 — Total power at the output
Total input power:1 W+1 W=2 W1\,\text{W} + 1\,\text{W} = 2\,\text{W}1W+1W=2W
Since the combiner is lossless:
Pout=2 WP_{\text{out}} = 2\,\text{W}Pout=2W
Step 4 — Output voltage check (sanity check)
Into 50 Ω:Vout=2×50=10 V rmsV_{\text{out}} = \sqrt{2 \times 50} = 10 \text{ V rms}Vout=2×50=10 V rms
So:
- Each source contributes coherently
- The network transforms things so the combined result is 10 V rms into 50 Ω
- That corresponds to 2 W, not 4 W
Why not 4 W?
The “4 W” result comes from naively adding voltages directly:(7.07+7.07)2/50=4 W(7.07 + 7.07)^2 / 50 = 4\,\text{W}(7.07+7.07)2/50=4W
But that assumes:
- You physically forced both sources into the same node without impedance transformation
- That condition would violate the 50 Ω match
- The sources would fight each other
- You’d get reflections or current redistribution—not extra power
The key constraint
A passive, lossless RF network obeys:Pout≤∑PinP_{\text{out}} \le \sum P_{\text{in}}Pout≤∑Pin
So:
- Best possible outcome → 2 W
- Never 4 W
