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SPP/ FIELDS Modes and Operations

SPP/ FIELDS Modes and Operations. Stuart D. Bale, Keith Goetz 18 July 2013. FIELDS Clocks. FIELDS instrument to use unified clocking Receivers, sampling, power supplies, clocks FIELDS HF instrument relies on picket-fence for RF sensitivity

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SPP/ FIELDS Modes and Operations

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  1. SPP/FIELDSModes and Operations Stuart D. Bale, Keith Goetz 18 July 2013

  2. FIELDS Clocks • FIELDS instrument to use unified clocking • Receivers, sampling, power supplies, clocks • FIELDS HF instrument relies on picket-fence for RF sensitivity • Power supplies chop – making lines noise as a function of frequency • Un-avoidable but controllable chopping at controlled frequencies • All power supplies must be controlled • N * 50kHz with N starting at 3 – e.g. 150kHz, 200kHz and so on • Frequencies are crystal controlled (±100PPM) • Make observations as a function of frequency in between lines of noise • In earlier analog super-heterodyne receivers, we used sharp crystal filters to create the picket fence • Observing in between lines of noise

  3. Picket Fences

  4. FIELDS Clocks • In the past, we used sharp crystal filters to create the picket fence • With our new all-digital receiver, we implement sharp picket-fence filteringwith simple time series and poly-phase filtering • Samples must be in sync with FIELDS’ and S/C power supplies • FIELDS/HFR high end is about 20MHz – sampling at ~40MSa/s • Exact frequency must fall on the picket fence with room for an FFT • Master sampling frequency is thus of the form 150kHz * 2^N • Master sampling frequency is 150,000 * 256 Hz is 38,400,000Hz

  5. FIELDS Clocks • Master clock is 38,400,000Hz (±4kHz) • Power supply chopping frequency is 150,000Hz • 38,400,000Hz / 256 • Other FIELDS instruments will be operated in synchronization with master clock and power supply chopping frequency (SWEAP too?) • For low frequencies we’ll shift down by powers of two to ~293 Sa/s • 150,000kHz / 512 (292.968750Sa/s) • However, making convenient and compressible packets still requires a packet size and cycle time corresponding to a power of 2 samples • A standard packet should start with 256 vectors • Giving a FIELDS internal cycle time of .87 seconds/cycle • 131,072 / 150,000 Hz • FIELDS’ New York second

  6. FIELDS DC MAG • Two DC MAGs – in-board and out-board • Designed and built at GSFC • Two units are to be identical • Identical drive frequencies • Identical range and resolution – 3 ranges up to ±64knT • Identical AC heater frequencies (150kHz) • Identical sampling rates: ~293 Sa/s or 292.96875 Sa/s or 150,000/512 Sa/s • Sync’ed to overall FIELDS master clock • Sync’ed to SWEAP clock? • Common hardware interfaces to FIELDS’ DCB and TDS • Common flight software modes • MAGs produce chunks/packets at 256 vectors per cycle • MAGs produce samples at ~293 vectors per second • Out-board MAG survey data down-sampled by 8 to ~36.3 vectors/second • In-board MAG survey data down-sampled by 128 to ~2.3 vectors/second

  7. FIELDS DC MAG • MAGs produce samples at ~293 vectors per second • Out-board MAG survey data down-sampled at ~36.3 vectors/second • In-board MAG survey data down-sampled at ~2.3 vectors/second • MAG telemetry chunks/messages/packets • Continuous B(t) - edge to edge • .87 seconds/cycle (131,072/150,000Hz ) • Powers of 2 vectors in length – nominally 256 vectors/packet • Powers of 2 cycles (.87s) in length • Ranges from • 256 vectors at 293Sa/s covering .87s and 1 cycle in duration – highest resolution • 256 vectors at 36.3Sa/s covering 7s and 8 cycles in duration – out-board nominal • 256 vectors at 2.3Sa/s covering 111s and 128 cycles in duration – in-board nominal • 256 vectors at 1.2Sa/s covering 222s in 256 cycles in duration – lowest resolution • MAG range/gain changes • Allowed between cycles (256 vector samples or .87s)

  8. FIELDS AC SCM • AC Search-Coil Magnetometers (SCM) • Designed and built at Orleans • 3 Low Frequency axes - 1 Mid Frequency axis • FIELDS DFB – can sample all 4 SCM axes and all 5 electric axes • Sampled at 150,000Sa/s • Down sampled in powers of two • Lowest rate is ~293 Sa/s or 292.96875 Sa/s or 150,000/512 Sa/s • SCM telemetry chunks – continuous time series - edge to edge • Nominally 2 V(t), 3 E(t) and 3 B(t) • .87 seconds/cycle (131,072/150,000Hz ) • Powers of 2 samples in length • Powers of 2 cycles (.87s) in length • Low frequency DFB packets • 256 vectors at 293Sa/s covering .87s and 1 cycle in duration – lowest resolution • DFB samples in sync with DC MAGs

  9. FIELDS AC SCM • DFB can sample from all 4 SCM axes and all 5 electric axes • Sampled at 150,000Sa/s • DFB low-frequency spectra • 4 spectra – 2 cross spectra - 112 log-spaced channels up to 9.4kHz • 1 cycle – .87s per spectrum – continuous coverage • DFB mid-frequency spectra • 4 spectra – 2 cross spectra – 112 log-spaced channels up to 75kHz • 60 cycles – 52s per spectrum continuous coverage • DFB mid-frequency select time series • Nominally 3 E(t) and 3 AC B(t) • Sampled at 150,000Sa/s • Burst triggered based on programmable quality • Recorded at 1% duty cycle in FIELDS’ internal memory throughout perihelion • Later selected and sent to telemetry by command

  10. FIELDS AC SCM • TDS – 1 SCM axis • Time series triggered bursts sampled at ~2MSa/s • Burst snapshots simultaneous with V, E and SWEAP counts • RFS – 1 SCM axis • Sampled at ~40MSa/s • Spectra downsampled to 1MHz (~2MSa/s)

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