Temperature stability of AirSpy SDR receiver

Hardware Quartz (E4000+RTL2832) AirSpy TCXO After warm-up 293'627'555 Hz +89.49ppm 293'601'318 Hz +0.129ppm Tcase ~0C 293'626'824 Hz +87.00ppm 293'601'185 Hz -0.324ppm Tcase ~60С 293'628'227 Hz +91.78ppm 293'601'386 Hz +0.361ppm

AirSpy TCXO

Quartz (E4000+RTL2832)

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Recently I got AirSpy SDR-receiver : it has 20Mhz/12bit ADC which is a significant improvement to 2.4Mhz/8-bit one in RTL2832-based devices. Capture bandwidth is 9Mhz. Also, it uses TCXO with 1.5ppm frequency error spec. In this article I focus on it's frequency error vs temperature.BTW, for the first time in human history we have blueberry-cooled electronics:Here are frequency errors. I was measuring 35-th harmonic of FE-5680A rubidium frequency standard generating 2^23 Hz, i.e. ideal frequency should have been 8192*1024*35=293'601'280 Hz.This is FE-5680A used during the test. I'll try to write about it's modification and interface board later...Temperature coefficient is quite nonlinear in cold (<10C) and hot(>45C) regions. Also, there is a ~0.061ppm jump in frequency during every cool-down period (at Tcase of ~5-10C ). Once I even observed 3 smaller jumps instead of 1 larger. Anyway, frequency error is well within 1.5ppm datasheet spec.Temperature coefficient appeared to be much smaller than I expected, and more linear/monotonic. Obviously it lacks factory precalibration, so base frequency error is quite large. Temperature-induced frequency error is 7 times worse than AirSpy's TCXO. Note that frequency scale is different.AirSpy looks good in terms of frequency stability - with it's perfect factory calibration, and better-then-datasheet frequency error (0.361 vs 1.5ppm). Comparing to quartz it's initial accuracy is 2 orders of magnitude better, and temperature-induced frequency shift is 7 times better (0.685ppm total vs 4.78ppm).Phase noise comparison is still an open question.