Expert-level radio astronomy covering radio telescopes, interferometry, VLBI, pulsars, spectral line observations, fast radio bursts, and aperture synthesis imaging.
Single dish: large collecting area, resolution limited by diffraction. Parabolic reflector: focuses radio waves to receiver at prime or secondary focus. FAST: 500m dish in China, most sensitive single dish in the world. Receiver systems: LNA amplifiers, mixers, spectrometers, cryogenic cooling. System temperature: receiver noise plus sky background limits sensitivity.
Baseline: separation between two antennas, determines angular resolution. Visibility: complex number measured by each baseline, Fourier transform of sky. UV plane: spatial frequency coverage determines image quality. Aperture synthesis: Earth rotation fills UV plane over time. CLEAN algorithm: iterative deconvolution of dirty beam from dirty image.
Very long baseline interferometry: intercontinental baselines, microarcsecond resolution. Atomic clocks: GPS and hydrogen masers synchronize stations. EHT: global VLBI at 1.3mm imaged black hole shadows of M87 and Sgr A star. Space VLBI: RadioAstron satellite extended baselines beyond Earth diameter.
Pulsars: rotating neutron stars, stable rotation used as precise clocks. Pulsar timing arrays: gravitational wave background detection method. FRBs: fast radio bursts, millisecond transients, largely extragalactic origin. HI 21cm line: neutral hydrogen spin-flip transition traces galaxy structure. Molecular lines: CO, OH, NH3 probe cold gas in star-forming regions.
| Pitfall | Fix |
|---|---|
| RFI contamination | Flag affected data before imaging |
| Insufficient UV coverage | Observe at multiple hour angles or add more antennas |
| CLEAN divergence | Use appropriate CLEAN depth and mask region |
| Confusing flux density and luminosity | Always specify distance when quoting luminosity |