Names are broken down into the standard parts, DeviceType : Area : Position : Attribute
Name | Description |
---|---|
ACCL | Used for everything in the RF system that is part of the general physics and operations interface at the cavity level |
CMOD | Used for everything in the RF system that is part of the general physics and operations interface at the cryomodule level (Gang phase and LEM computations) Comment by Sonya 1/17/18: Remind me why we need this: can't we just use ACCL:L1B:1500:PDES, for example? |
GUN | Used for everything in the gun |
Buncher? | |
PRC/RFS/RES/SSA | Used for engineering diagnostics related to a specific control chassis, such as chassis health monitors. They names correspond to the chassis types: Precision Receiver Chassis, RF Chassis, Resonance Chassis, Solid State Amplifier |
See https://slacspace.slac.stanford.edu/sites/lcls/lcls-2/wd/dsg/Forms/AllItems.aspx, Naming Convention section 6.1.2.2
Area | Physical Location |
---|---|
GUNB | LCLS-II Gun |
L0B | LCLS-II L0 Accelerator Region |
L1B | LCLS-II L1 Accelerator Region |
BC1B | LCLS-II Bunch Compressor 1 |
L2B | LCLS-II L2 Accelerator Region |
BC2B | LCLS-II Bunch Compressor 2 |
L3B | LCLS-II L3 Accelerator Region |
SYS2 | Full LCLS-II Accelerator scope, e.g. global phase offset |
See https://slacspace.slac.stanford.edu/sites/lcls/lcls-2/wd/dsg/Forms/AllItems.aspx, Naming Convention section 6.1.2.3.2
Cryo Module # | Description |
01-35 | CM01-CM35, 1.3GHz cavity |
H1 | 3.9GHz Cryomodule 1, located in L1B and follows CM03 |
H2 | 3.9GHz Cryomodule 2, located in L1B and follows H1 |
Numbering of cavities within a cryomodule:
Name | Description | |||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
GDES | Operation Gradient setpoint (MV/m) - Possibly deprecate | |||||||||||||||
GACT | Measured gradient from cavity probe (MV/m) | |||||||||||||||
GMAX | Maximum allowable gradient (MV/m) | |||||||||||||||
GCAL | Gradient calibration scale factor, nominally 1. Multiply by this when calculating raw register value to set, so increasing GCAL increases output. | |||||||||||||||
ADES | Operation Amplitude setpoint (MV) | |||||||||||||||
AACT | Measured amplitude from cavity probe (MV) | |||||||||||||||
AMAX | Maximum allowable amplitude (MV) | |||||||||||||||
ACAL | Amplitude calibration scale factor, nominally 1. Multiply by this when calculating raw register value to set, so increasing GCAL increases output. | |||||||||||||||
PDES | Operation Phase setpoint (degrees, where 0 is on-crest) | |||||||||||||||
PACT | Measured phase from cavity probe (degrees) | |||||||||||||||
PREF | a.k.a.gold, phase offset used by LLRF to convert measured phase to one relative to on-crest operation, adjusted by beam phasing (detrees) | |||||||||||||||
DETDES | Cavity detuning setpoint (Hz) | |||||||||||||||
DETACT | Detune seen by the resonance system (Hz) | |||||||||||||||
Mode | RF mode (off, pulsed, SEL, GDR) | |||||||||||||||
RFCTRL | Master enable for an RF cavity (On, Off) \[How to distinguish this from the SSA specific RF enable register?] | |||||||||||||||
RFReady | Status of RF controls, (Ready, Not Ready) set to ready when control loops are closed and RF is continuous. Or will we ever run with pulsed RF? | |||||||||||||||
Quench | Status showing when a cavity quenches, from interlocks (Normal, Quenched) | |||||||||||||||
STAT | Status bits in software (define the bits) | |||||||||||||||
HSTA | Hardware status | |||||||||||||||
GTRACE | Gradient waveform from the cavity probe, which is used to calculate GACT (MV/m) | |||||||||||||||
PTRACE | Phase waveform from the cavity probe, which is used to calculate PACT (degrees) | |||||||||||||||
*ERRTRACE | Error waveforms corresponding to waveforms above, captured and put in a separate buffer when a fault is detected (degrees or MV/m) | |||||||||||||||
Any of the above in I/Q equivalent of Amplitude/Phase | ||||||||||||||||
PwrFwd | Forward power from SSA to cavity | |||||||||||||||
PwrRev | Reflected/reverse power from cavity | |||||||||||||||
PzWF | Waveforms from tuner piezo motors, useful for finding microphonics. Units TBD. | |||||||||||||||
ALEM | LEM computed integrated RF amplitude (MV) per cavity and per cryomodule | |||||||||||||||
PLEM | LEM computed phase (deg) | |||||||||||||||
EGLEM | LEM computed energy gain (MeV) | |||||||||||||||
CHLEM | LEM computed chirp (MeV) | |||||||||||||||
Waveform Signals | ||||||||||||||||
The PVs below will be provided for each waveform signal. Each cavity has the following waveform signals:
| ||||||||||||||||
Waveform | <SIG>:ATRACE | Signal amplitude waveform | ||||||||||||||
Statistics | <SIG>:AMEAN | Mean of <SIG>:ATRACE | ||||||||||||||
<SIG>:ASTD | Standard deviation of <SIG>:ATRACE | |||||||||||||||
<SIG>:AMIN | Minimum of <SIG>:ATRACE | |||||||||||||||
<SIG>:AMAX | Maximum of <SIG>:ATRACE | |||||||||||||||
Waveform | <SIG>:PTRACE | Signal phase waveform | ||||||||||||||
Statistics | <SIG>:PMEAN | Mean of <SIG>:PTRACE | ||||||||||||||
<SIG>:PSTD | Standard deviation of <SIG>:PTRACE | |||||||||||||||
<SIG>:PMIN | Minimum of <SIG>:PTRACE | |||||||||||||||
<SIG>:PMAX | Maximum of <SIG>:PTRACE | |||||||||||||||
Waveform | <SIG>:PWRTRACE | Signal power waveform | ||||||||||||||
Statistics | <SIG>:PWRMEAN | Mean of <SIG>:PWRTRACE | ||||||||||||||
<SIG>:PWRSTD | Standard deviation of <SIG>:PWRTRACE | |||||||||||||||
<SIG>:PWRMIN | Minimum of <SIG>:PWRTRACE | |||||||||||||||
<SIG>:PWRMAX | Maximum of <SIG>:PWRTRACE | |||||||||||||||
Waveform | <SIG>:ITRACE | Signal I waveform | ||||||||||||||
Waveform | <SIG>:QTRACE | Signal Q waveform |
By default, these should be write-protected during operation
Name | Description |
---|---|
(from Chris Adolfsen. Garth wonders should this be a calibration attribute rather than physics interface?) Slow tuner start-up position prior to rf turn on - with the piezo voltages zeroed, the cavity would be tuned close to 1.3 GHz after the operating gradient is established - thus the initial detuning with rf off relative to 1.3 GHz is K*(operating gradient)^2 | |
(from Chris Adolfsen. Garth wonders should this be a calibration attribute rather than physics interface?) Slow tuner park position - this is the position the tuner would be set if one wants to detune the cavity so it does not interact with the beam. | |
Q0 | Q0 measurement from partner labs, delivered with the cryomodule |
Qext | Qext measured in-situ (last measurement – used to calibrate cavity probe signal based on discharge power) |
LFD | Lorentz Force Detuning K factor(Hz/(MV/m)^2) measured in-situ |
Calibration of the slow tuner (Hz/step) measured in-situ | |
Calibration of the piezo tuners (Hz/volt) measured in-situ | |
Cables and couplers loss, combined with sensor sensitivity, as a scale factor to multiply raw reading by to get MV/m | |
Attenuator value, combined with the above as a multiplier to convert raw to units. Probalby in dB | |
Chassis and ADC scale factor, or polynomial coefficients. From lab measurements of chassis to convert ADC units to physics units | |
PI(no D) loop parameters for amplitude and phase loops. Maybe PKp, PKi, GKp, GKi | |
Open loop amplitude and phase DAC settings | |
Control loop status (open, closed) | |
Name | Description |
---|---|
VacStat | Vacuum interlock status (Good, Faulted) \[NOTE: Details needed for specifying which vacuum status bit, coupler or beamline] |
TStat | Temperature interlock status (Good, Faulted) \[NOTE: Details needed for specifying which temperature status bit, coupler or stepper.] |
Temperature interlock threhshold | |
V | Chassis power supply voltage |
T | Chassis board temperature |
DC | SSA enable/disable internal DC power |
SSA RF enable, how to distinguish from global RF enable? | |
PzVout | Output voltage to the piezo tuning motor |
PzHz | Expected tuning change from PzVout |
Name | Description |
---|---|
Firmware MD5 | |
BMB7 board serial # | |
Digitizer board serial # | |
Chassis serial # and/or Depot number |