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--- teamb2023 [2023/02/23 02:36] – [Hardware availability] nuicise
+++ teamb2023 [2023/03/19 22:02] (current) – [Team B] nuicise
@@ Line 4: / Line 4: @@
 **Supporter**: Ph.D. student Quyen Phan; M.Sc. Sang Truong
+**Members**:
+  * Nguyen Thi Yen Binh
+  * Trinh Hoang Dieu Ngan
+  * Dang Quoc Trieu
+  * Nguyen Duc Phu
+  * Nguyen Thi Nhung
+[[https://ifirse.icise.vn/nugroup/hardwarecamp/uploads/Hardware_Camp_Beamer-GroupB.pdf|Group B Final presentation]] and [[https://ifirse.icise.vn/nugroup/hardwarecamp/uploads/GroupB%20-%20Hardware%20Camp%20Report.pdf|final report]]
 ===== Targets =====
-  * MPPC properties
+  * **MPPC properties**
     * observe 1pe, 2pe and the corresponding threshold
-    * check the rising/falling time
+    * check the rising/falling time (note the definition of the rising and falling time)
     * dark count rate with 1pe; 2pe; 3pe
     * check `pattern` trigger (need calibration?) with coincidence of 2, 3
-      * Use DRS4 waveform generator for example
+      * Use DRS4 waveform generator (or Arduino) for example
       * Coincidence gate
-  * Fluorescence lifetime by exciting with UV LED (using SUM channel? )
+  * **Fluorescence lifetime by exciting with UV LED**
+    * Measure rising/falling time with oscilloscope (note the signal size)
     * Fit with exponential and/or oscilloscope measurement function
-  * Cosmic muon counter
+  * **Cosmic muon counter**
     * calculate the rate with area of detector (size of plastic scintillator)
     * Scintillator inefficiency (rate of 1,2,4; vs rate of 1,2,3,4)
@@ Line 22: / Line 31: @@
 ===== Hands-on Activities =====
-. Act#1 (1.5h): safety, lab arrangement, components, rules; light source (LED)  driven with 1. Act#1 (1.5h, Feb. 27 AM): safety, lab arrangement, components, rules; light source (LED)  driven with waveform generator, arduino or analog discovery; various LED wavelength; soldering a circuit for LED (this is to use with MPPC later, so think a bit about design to easily coupling to MPPC (direct or with optical fibers, mimicking the use of the WLS))
+. Act#1 (1.5h, Feb. 27 AM): safety, lab arrangement, components, rules; light source (LED)  driven with waveform generator, arduino or analog discovery; various LED wavelength; soldering a circuit for LED (this is to use with MPPC later, so think a bit about design to easily coupling to MPPC (direct or with optical fibers, mimicking the use of the WLS))
-. Act #2 (1.75h, Feb. 27 PM) oscilloscope, signal generation (with NIM or function generation); MPPC (a SiPM type) circuit,
+. Act #2 (1.75h, Feb. 27 PM) oscilloscope functionality, signal generation with analog discovery, counting function  and coincidence pattern trigger
-. Act #3 (2.75h, Feb. 28 AM): MPPC circuit; soldering, testing signal, pedestal; noise mitigation with Faraday case
+. Act #3 (2.75h, Feb. 28 AM): Single MPPC circuit; soldering, testing signal, pedestal; noise mitigation with Faraday case, checked if can see single P.E without amplifier?
-.  Act #4 (2.75h, Feb. 28 PM): Light tightening; MPPC characteristics (noise rate, gain, supply voltage dependence; timing response); measure the speed of light in the optical fibers if having time (concept of light detection and ranging or LiDAR in short); NIM modules to use: disciminator and scaler
+.  Act #4 (2.75h, Feb. 28 PM): Start working with MPPC array; measure MPPC characteristics (noise rate, gain; timing response); measure the fluorescence lifetime with Thorlabs fluorescence plates
-.  Act #5 (2.75h, Mar. 1 AM): Work in combination of Scintillator, wavelength shifting fiber and photosensor; concept of muon counter; NIM modules to use: discriminator, scaler, coincidence (and delay if needed)
+.  Act #5 (2.75h, Mar. 1 AM): Continue with fluorescence lifetime measurement if needed. measure coincidence rate. Work in combination of Scintillator, wavelength shifting fiber and photosensor; concept of muon counter; NIM modules to use: discriminator, scaler, coincidence (and delay if needed)
 .  Act #6 (2.75h, Mar. 1 PM): Data taking and analysis
@@ Line 43: / Line 52: @@
   * MPPC array 4 x4, model Hamamatsu S13361-3050AE-04, specification [[https://www.hamamatsu.com/content/dam/hamamatsu-photonics/sites/documents/99_SALES_LIBRARY/ssd/s13361-3050_series_kapd1054e.pdf]]
     * AiT power supply [[model ABPS]] and amplifier [[model PBA116L]]
-  * One single MPPC S13360-1225 [[https://www.hamamatsu.com/content/dam/hamamatsu-photonics/sites/documents/99_SALES_LIBRARY/ssd/s13360_series_kapd1052e.pdf]]: try to soldering; check and suppress the noise. No need amplifier to observe the signal; use along with Matsusada power supply
+  * One single MPPC S13360-1225 [[https://www.hamamatsu.com/content/dam/hamamatsu-photonics/sites/documents/99_SALES_LIBRARY/ssd/s13360_series_kapd1052e.pdf]]: try to soldering; check and suppress the noise. No need amplifier to observe the signal; use along with Matsusada low-noise DC power supply
   * 4 plastic scintillator  and wavelength shifting fiber
-  * AiT power supply and amplifier board, model
+    * size: **2.5cm width x 1.3 cm thick x 25 cm long**
   * Oscilloscope SDS 1104X-E/ with ethernet connected [[https://siglentna.com/USA_website_2014/Documents/UserManual/SDS1000X&Xplus_UserManual_UM0101X-E02A.pdf]]
   * Optical fibers (Thorlabs 2m) and unknown
-  * DAQ PC: IFIRSE06
+  * DAQ PC: IFIRSE06/ Ubuntu 22.04; relevant software available: ROOT, GEANT4