Discussion Overview
The discussion revolves around the phase relationship between input and output voltages at high frequencies for a given transfer function. Participants explore the implications of high-frequency behavior, particularly in relation to phase shifts introduced by poles in the transfer function.
Discussion Character
- Homework-related
- Technical explanation
- Debate/contested
Main Points Raised
- One participant initially calculated the phase at very high frequencies to be 0°, questioning the discrepancy with the teacher's answer of -180° due to the presence of two poles.
- Another participant suggested substituting jω for s to analyze the phase angle, noting that j corresponds to +90 degrees and exploring the implications of j².
- Some participants agreed that the formula was correct but expressed confusion over why substituting ω as infinity did not yield -180°.
- One participant advised keeping the x and y components separate rather than forming a ratio for the arctan function, suggesting that this could clarify the phase behavior as frequency increases.
- There was a query about whether higher frequencies could be assumed to be above the cutoff frequency, to which a participant confirmed that this assumption is valid.
- Another participant noted that the phase approaches -180° at very high frequencies but never actually reaches it, suggesting the use of tools like Bode Plot for further analysis.
Areas of Agreement / Disagreement
Participants express differing views on the calculation of phase at high frequencies, with some supporting the teacher's answer of -180° while others remain confused about the methodology leading to that conclusion. The discussion does not reach a consensus on the correct phase value.
Contextual Notes
Participants highlight the ambiguity in the arctan function and the behavior of the phase as frequency approaches infinity, indicating that assumptions about frequency ranges and pole contributions may affect the results.