dim:appnotes:llrf_two_cav
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| dim:appnotes:llrf_two_cav [2018/09/12 04:26] – dim | dim:appnotes:llrf_two_cav [2018/10/05 16:10] (current) – dim | ||
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| Re-check that tuner error is zero and cavity is still tuned on resonance. If so, turn on the tuner loop (this procedure assumes tuner loop gain and sign have been previously configured). Record the current setting of the tuner loop deadband and set it (temporarily) to 0.1 degrees. Re-enable RTNA sweep and use the code provided above to read out cavity response and to verify on-resonance condition. With tuner loop closed, make fine adjustments to cavity forward phase offset to bring the cavity detuning to zero (typical variation from measurement to measurement will be ±200(nbsp)Hz). | Re-check that tuner error is zero and cavity is still tuned on resonance. If so, turn on the tuner loop (this procedure assumes tuner loop gain and sign have been previously configured). Record the current setting of the tuner loop deadband and set it (temporarily) to 0.1 degrees. Re-enable RTNA sweep and use the code provided above to read out cavity response and to verify on-resonance condition. With tuner loop closed, make fine adjustments to cavity forward phase offset to bring the cavity detuning to zero (typical variation from measurement to measurement will be ±200(nbsp)Hz). | ||
| + | ===== Vector sum configuration ===== | ||
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| + | Once both cavities are tuned on resonance, it's time to configure the vector sum signal. Cavity vector sum signal is calculated in real time by LLRF9 FPGA and is compared to the cavity setpoint in the closed loop operation to generate the feedback loop error signal. The error signal is amplified by proportional and integral loops to derive appropriate klystron/ | ||
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| + | Probe signals from two cavities pass through digital gain/phase blocks before being summed together. Gain/phase block can be used to apply arbitrary phase shift and attenuation to the probe signal. | ||
dim/appnotes/llrf_two_cav.1536726388.txt.gz · Last modified: 2018/09/12 04:26 by dim