tuning_the_s800_xdt
Differences
This shows you the differences between two versions of the page.
| Both sides previous revision Previous revision Next revision | Previous revision Next revision Both sides next revision | ||
|
tuning_the_s800_xdt [2015/10/26 14:08] pereira [Reaction Setting] |
tuning_the_s800_xdt [2015/10/26 14:09] pereira [Setting up Reaction Settings] |
||
|---|---|---|---|
| Line 255: | Line 255: | ||
| - | |||
| - | |||
| - | ==== Coincidences ==== | ||
| - | |||
| - | * Overview | ||
| - | * Most experiments at the S800 involve setting up an auxiliary detector system (e.g. SeGA, HiRA, etc) to be used in coincidence with the standard detectors of the S800. | ||
| - | * The auxiliary detector provides a secondary trigger that is fed into the S800 trigger system | ||
| - | * A key part of setting up the S800 for such experiments is getting proper timing setup between the S800 and any auxiliary detectors | ||
| - | * For cases where the Secondary detector has a slow response relative to the S800, the coincidence timing must be reset to the S800 timing by delaying the S800 trigger using the third gate and delay generator on the trigger GUI | ||
| - | * A typical S800 delay for SeGA is 450 ns | ||
| - | * Probably smaller typical S800 delay needed for HiRA | ||
| - | * An example of experiments where auxiliary detectors are not used and, thus, setting up coincidence timing is not an issue are the experiments with tritons run by the charge exchange group | ||
| - | * It is not clear whether coincidence setup gets logged as “XDT” or “EXR” | ||
| - | |||
| - | * Choice of setting to be used for coincidence timing setup | ||
| - | * The reaction of interest for the experiment can be used to setup coincidences only if the rate of coincidences is high enough | ||
| - | * Sometime the pilot beam is used for setting up the coincidence timing in cases where the intensity of the secondary beam is too small | ||
| - | * Example: | ||
| - | |||
| - | * Setup | ||
| - | * Coincidence signals are usually visible on scope without running scope in acquire mode | ||
| - | * Adjust the width of the early signal (S800 or secondary) should be wide enough to catch coincidences with the late signal (width of late signal is not critical) | ||
| - | * Readjust TDC delays based on changes made to S800 trigger delay | ||
| - | * Experimenters will need to adjust their delays based on delay made to S800 trigger | ||
| - | * Have experimenters record a run with coincidences on their account | ||
| - | * S800 trigger TDC channel should show a peak (which corresponds to coincidences) | ||
| - | * " | ||
| - | * This check is required for verification in cases of low beam intensity (e.g. 1000 pps) | ||
| - | * Length of run required is typically about 10-15 minutes | ||
| - | * To be resolved: | ||
| - | |||
| - | * Sample timing for running S800 with SeGA | ||
| - | * SeGA trigger is late with respect to S800 trigger | ||
| - | * The figure below represents a timing schematic to show how to | ||
| - | * Setup of the S800 trigger to recover timing needed for proper functioning of S800 FP detectors | ||
| - | * Set up the coincidence trigger | ||
| - | * See: http:// | ||
| - | |||
| - | {{: | ||
| - | |||
| - | * A double peak structure will appear in the TDC for the S800 trigger between the coincidence events and the singles events (see figure below); the groups are separated by 25 ns because of the delay introduced by the downscaler used for the singles | ||
| - | |||
| - | {{: | ||
| Line 403: | Line 360: | ||
| * What experimenters want (e.g., if they want singles, the cut has to be more restrictive to limit acquisition deadtime) | * What experimenters want (e.g., if they want singles, the cut has to be more restrictive to limit acquisition deadtime) | ||
| * Move blocker, decrease attenuator, repeat | * Move blocker, decrease attenuator, repeat | ||
| + | |||
| + | |||
| + | |||
| + | |||
| + | |||
| + | ===== Coincidences ===== | ||
| + | |||
| + | * Overview | ||
| + | * Most experiments at the S800 involve setting up an auxiliary detector system (e.g. SeGA, HiRA, etc) to be used in coincidence with the standard detectors of the S800. | ||
| + | * The auxiliary detector provides a secondary trigger that is fed into the S800 trigger system | ||
| + | * A key part of setting up the S800 for such experiments is getting proper timing setup between the S800 and any auxiliary detectors | ||
| + | * For cases where the Secondary detector has a slow response relative to the S800, the coincidence timing must be reset to the S800 timing by delaying the S800 trigger using the third gate and delay generator on the trigger GUI | ||
| + | * A typical S800 delay for SeGA is 450 ns | ||
| + | * Probably smaller typical S800 delay needed for HiRA | ||
| + | * An example of experiments where auxiliary detectors are not used and, thus, setting up coincidence timing is not an issue are the experiments with tritons run by the charge exchange group | ||
| + | * It is not clear whether coincidence setup gets logged as “XDT” or “EXR” | ||
| + | |||
| + | * Choice of setting to be used for coincidence timing setup | ||
| + | * The reaction of interest for the experiment can be used to setup coincidences only if the rate of coincidences is high enough | ||
| + | * Sometime the pilot beam is used for setting up the coincidence timing in cases where the intensity of the secondary beam is too small | ||
| + | * Example: | ||
| + | |||
| + | * Setup | ||
| + | * Coincidence signals are usually visible on scope without running scope in acquire mode | ||
| + | * Adjust the width of the early signal (S800 or secondary) should be wide enough to catch coincidences with the late signal (width of late signal is not critical) | ||
| + | * Readjust TDC delays based on changes made to S800 trigger delay | ||
| + | * Experimenters will need to adjust their delays based on delay made to S800 trigger | ||
| + | * Have experimenters record a run with coincidences on their account | ||
| + | * S800 trigger TDC channel should show a peak (which corresponds to coincidences) | ||
| + | * " | ||
| + | * This check is required for verification in cases of low beam intensity (e.g. 1000 pps) | ||
| + | * Length of run required is typically about 10-15 minutes | ||
| + | * To be resolved: | ||
| + | |||
| + | * Sample timing for running S800 with SeGA | ||
| + | * SeGA trigger is late with respect to S800 trigger | ||
| + | * The figure below represents a timing schematic to show how to | ||
| + | * Setup of the S800 trigger to recover timing needed for proper functioning of S800 FP detectors | ||
| + | * Set up the coincidence trigger | ||
| + | * See: http:// | ||
| + | |||
| + | {{: | ||
| + | |||
| + | * A double peak structure will appear in the TDC for the S800 trigger between the coincidence events and the singles events (see figure below); the groups are separated by 25 ns because of the delay introduced by the downscaler used for the singles | ||
| + | |||
| + | {{: | ||
| + | |||
tuning_the_s800_xdt.txt · Last modified: 2023/09/22 15:15 by swartzj
Page Tools
Except where otherwise noted, content on this wiki is licensed under the following license: CC Attribution-Noncommercial-Share Alike 4.0 International
