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RISING stopped beam trigger

RISING stopped beam trigger. Take Saito and Nik Kurz. Two types of trigger. Prompt trigger Request to the DAQ system for the data taking By sending NIM/ECL logic signals to the trigger module Data conversion is started by the prompt trigger Trigger timing well defined

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RISING stopped beam trigger

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  1. RISING stopped beam trigger Take Saito and Nik Kurz

  2. Two types of trigger • Prompt trigger • Request to the DAQ system for the data taking • By sending NIM/ECL logic signals to the trigger module • Data conversion is started by the prompt trigger • Trigger timing well defined • Delayed trigger (a few hundreds nanoseconds to a few tens of micro seconds) • Cancellation of the data into the stream • Frequently used example : Fast clear • Trigger timing has not to be defined Clever experiments combine these two types in multiple levels

  3. Very easy case : RISING fast beam trigger • Ge + plastic coincidence trigger • Timing defined by the fastest detector : Plastic • Obviously … Plastic Ge

  4. Very easy case : RISING fast beam trigger • Ge + plastic coincidence trigger • Timing defined by the fastest detector : Plastic • Obviously … Plastic Ge 500 ns

  5. Very easy case : RISING fast beam trigger • Ge + plastic coincidence trigger • Timing defined by the fastest detector : Plastic • Obviously … Plastic Ge 500 ns

  6. Very easy case : RISING fast beam trigger • Ge + plastic coincidence trigger • Timing defined by the fastest detector : Plastic • Obviously … Plastic Ge 500 ns Coincidence 600 ns

  7. Very easy case : RISING fast beam trigger • Ge + plastic coincidence trigger • Timing defined by the fastest detector : Plastic • Obviously … Plastic Ge 500 ns Coincidence 600 ns Signals to ADC/QDC/TDC must be delayed by 600 ns

  8. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals

  9. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic

  10. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Ge

  11. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Ge

  12. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Ge

  13. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Ge Stretched coincidence

  14. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Delayed plastic Ge Stretched coincidence

  15. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Delayed plastic Ge Stretched coincidence Trigger

  16. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Delayed plastic Ge Stretched coincidence Trigger

  17. Another very easy case : Stopped beam trigger with a traditional way • Time gate opened by plastic signals • Trigger timing must be defined by plastic signals Delayed-stretched plastic Delayed plastic Ge Stretched coincidence Trigger Huge delay

  18. Stopped beam trigger with multiple levels • Trigger by fast plastic signals (up to a few k Hz) • Fast clear when Ge is not fired within the time gate Fast plastic

  19. Stopped beam trigger with multiple levels • Trigger by fast plastic signals (up to 10 k Hz) • Fast clear when Ge is not fired within the time gate Fast plastic Trigger Delayed-stretched plastic

  20. Stopped beam trigger with multiple levels • Trigger by fast plastic signals (up to 10 k Hz) • Fast clear when Ge is not fired within the time gate Fast plastic Trigger Delayed-stretched plastic Ge

  21. Stopped beam trigger with multiple levels • Trigger by fast plastic signals (up to 10 k Hz) • Fast clear when Ge is not fired within the time gate Fast plastic Trigger Delayed-stretched plastic Ge Fast clear

  22. Stopped beam trigger with multiple levels • Trigger by fast plastic signals (up to 10 k Hz) • Fast clear when Ge is not fired within the time gate Fast plastic Trigger Delayed-stretched plastic Ge Fast clear

  23. Stopped beam trigger with multiple levels • Trigger by fast plastic signals (up to 10 k Hz) • Fast clear when Ge is not fired within the time gate Fast plastic Trigger Delayed-stretched plastic Ge Fast clear • No delay needed for raw signals • Very flexible for isomer measurements (can be used as fast beam trigger)

  24. Some important issues • If you would implement different types of triggers (for example, singles, delayed singles, delayed coincidence ….) • Trigger must be tagged by • Some bit information in any of ADC/QDC/TDC …… • Trigger ID given by the VME trigger module • VXI Time information is only for “self-start self-stop” • Lifetime measurements must be done by other modules • TAC/TDC … • Do you need lifetime information with individual detectors?

  25. Who has to make triggers (not me) • My strong personal opinion (true in the most of good experiments) • There must be no universal trigger aiming different physics • Each experiment must have its own unique trigger • Large efficiency • Large signal/background ratio at the trigger level • High rate capability • Multi-levels : Easy to handle • Trigger has to be controlled by the spokesperson of the experiment • Good trigger already guarantees at least 50% of the success of the experiment • Trigger must be understood quantitatively • No guess please • How much background in the trigger level? • How much livetime? • ……………….

  26. Another important things • Trigger is highly related to DAQ • The person who will work on the trigger must know • How VME/VXI works • How the data stream looks like • How MBS works • Very strong cooperation with Nik Kurz • Independent diagnostic program to check triggers • Completely independent from spy and so on. • Special fast compact program only for the trigger diagnostic • Skill on the both hardware and software needed

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