Difference: CosmicRayLab (1 vs. 11)

Revision 112021-01-06 - JorgeRodriguez

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META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Cosmic Ray Lab

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In this lab you will measure the cosmic ray flux as a function of the zenith angle and determine its shape by fitting your data with a function that represent theoretical expectations. Does it conform to those expectations?
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In this lab, the primary goal is to measure the cosmic ray flux as a function of the zenith angle and determine its shape by fitting your data with a function that represents theoretical expectations. There is also a computing component in which you will use the Monte Carlo methods developed earlier to generate a sample of data simulating the data taken by the cosmic ray telescope under the circumstances you will follow to conduct the experiment. The lab is separated again into 3 parts, at first simulating the data on a computer before you embark on the actual experiment.

Part A: Generate a sample of simulated Cosmic Ray data

Here you are referred to the Particle Data Group's section on cosmic rays (Links to an external site.), which describes that the cosmic ray flux at the earth's surface is approximately determined to be distributed as ~ cos2(q). Here the angle is the azimuthal angle, where 0 is in the verticle direction and the functional form complies with the expectation that rays incident vertically are more probably than horizontally. There are a variety of effects contributing to this form, which you are encouraged to report on from your research, see PDG above. Here we will not attempt to simulate this distribution from first principles, although that could be done instead, you will take the shape as a given and create that on the computer, later confirming in real data.

In principle one could attempt to generate deviates drawn from a cos2 distribution as we did previously using conservation of probabilities and then solving for the angle in the argument but unfortunately integrating the cos2 function leads to a transcendental polynomial function which is somewhat difficult to deal with. Instead, we will employ a short cut given that we will be analyzing the data in terms of bins of azimuthal angles. We can thus use a Monte Carlo Poisson smearing on a bin by bin basis to create a simulated sample of data we can easily create on a computer. Here is how:

  1. First decide on a number of bins from or -pi/2 to + pi/2 corresponding to the range of position one can orient the CRT in. The center of these bins will be your azimuth angle q.
  2. Now create a "perfect" number of counts for each of the azimuth angle bins defined above using a formula such aLaTeX: N\left(\theta;\:t\right)=A\:+\:B\cos^2\left(\theta\right) here N represents the total number of cosmic ray events in a given interval of time so is unitless. The parameters A and B scale the function and capture the length of time over which the experiment is conducted, collection efficiencies, and allow for small but expected backgrounds. Remember you are collecting events if and only if both scintillators fire within a nanosecond or so so the likelihood of significant backgrounds are small.
  3. Now you will smear the "perfect" data count rate above by a Poisson. Remember histogram bins are Poisson so the mean is the count LaTeX: NN while the uncertainty is the LaTeX: \sqrt{N}N. These smeared counts will be the sample of simulated data you will use to compare to real data collected with the CRT.
 

Setup and calibration

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Before you begin your flux measurements you should become familiar with the experimental apparatus. To do this we'll first perform a calibration of the Cosmic Telescope, basically determine what high voltage to use for the PMT input and then take measurements of count rates before we plunge into our flux measurements.
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Before you begin your flux measurements you should become familiar with the experimental apparatus know here as the Cosmic Ray Telescope (CRT). To do this we'll first perform a calibration of the phototubes by determining at what high voltage gives a reliable number of counts, with minimal fluctuations vs. voltage.

Here how to do this

 
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First: Connect the HV supply to the PMTs and use the oscilloscope to find the output signal from the PMT. You will likely need to adjust the time scale or sweep (horizontal axis) and the voltage scale (vertical axis) on the scope. We expect output signals from the PMT to be 10-20 ns long and the output voltage to be a few millivolts for the Cosmic Ray telescope setup. You'll also need to set up the scope to self trigger on the output pulse; set the trigger to trigger on the channel the PMT output is on. Note that the output will only trigger the scope if it exceeds a set discriminator (disc) threshold (the "level" knob located on the trigger portion of the scope). Adjust the level knob to some fraction of the PMT's average output voltage. Since our PMT output voltage is negative you'll want to set the threshold below 0 V to display any events.
>
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First: Connect the HV supply to the PMTs and use the oscilloscope to find the output signal from the PMT. You will likely need to adjust the time scale or sweep (horizontal axis) and the voltage scale (vertical axis) on the scope. We expect output signals from the PMT to be 10-20 ns long and the output voltage to be a few millivolts for the Cosmic Ray telescope setup. You will also need to set up the scope on a self trigger mode or trigger on the PMT output. Note that the output will only trigger the scope if it exceeds a set discriminator (disc) threshold (this level is controlled by the "level" knob located on the trigger portion of the scope). Adjust the level knob to some fraction of the PMT's average output voltage. Since our PMT output voltage is negative you'll want to set the threshold below 0 V to display any events.
 
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Once you have your scope displaying multiple PMT pulses and have ascertained a reasonable value for your discriminator threshold you can take the PMT output and redirect it to the discriminator NIM module. As with the disc threshold on the scope the disc threshold on the NIM Module is used to filter out noise pulses from signal pulses. You can adjust the disc threshold on the NIM module by turning the tiny set screw hidden inside the whole labeled "THR". The threshold voltage can be read with a multimeter with leads connected to ground and the disc reading pad.
>
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Once you have your scope displaying multiple PMT pulses and have ascertained a reasonable value for your discriminator threshold you can take the PMT output and redirect it to the discriminator NIM module. As with the disc threshold on the scope, the disc threshold on the NIM Module is used to filter out noise pulses. You can adjust the disc threshold on the NIM module by turning the tiny set screw hidden inside the whole labeled "THR". The threshold voltage can be read with a multimeter with leads connected to the ground and the disc reading pad.
 
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Before you proceed with the experiments, PART A and B below lets first determine the proper input voltage to run the PMTs at, given the chosen disc threshold settings that you've selected. We do this to insure that the PMT pulses and thus count rates are stable across a sizable range of input voltages which may drift over the course of the experiment. We'll do this by measuring the count rate as a function of input voltage and look the input voltage that corresponds to start of the count plateau.
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Before you proceed with the experiments, PART B and C below lets first determine the proper input voltage to tune the PMTs for optimal performance, at the chosen disc threshold settings that you selected earlier. We do this to ensure that the PMT pulses and thus count rates are stable across a sizable range of input voltages. We will "calibrate: or AKA "plateau the PMT" by simply monitoring the count rate as a function of the input voltage. Make a plot of the input voltage on the PMT verse count rate using the counter NIM module and the radioactive source placed a few centimeters away from the scintillator. The proper input voltage will be somewhere on the "plateau" of that input voltage vs. counts you just made for the PMT.
 
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Begin by setting up the cosmic telescope by connecting the PMT output to the NIM discriminator then connect the disc output to the counter. Set the counter time window to collect a few 100 events. Make sure that you are counting real signals by insuring that the disc is set sufficiently high, check with the scope. Take count reading at various PMT input voltage and plot the results. Please DO NOT go beyond 2000 VOLTS. What you should see is that the count rates varies a lot when the voltage is set too high or too low. You'll want to use the a random event source, like the Sr 90 to insure you have real triggers instead of noise with proper disc setting. DO this for BOTH PMTs and provide in your lab report the plots you create.

Part A: Observation of Poisson and Gaussian distributions in radioactive decay of Sr 90.

>
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Begin by setting up the cosmic telescope by connecting the PMT output to the NIM discriminator then connect the disc output to the counter. Set the counter time window to collect a few 100 events. Make sure that you are counting real signals by ensuring that the disc is set sufficiently high, check with the scope. Take count reading at various PMT input voltage and plot the results. Please DO NOT go beyond 2000 VOLTS. What you should see is that the count rates vary a lot when the voltage is set too high or too low. You should use a random source of events, such as the Sr 90 source in the toolbox to ensure you have real triggers instead of noise. DO this for BOTH PMTs and include both plots in your lab report in the procedure section.

Part B: Observation of Poisson and Gaussian distributions from Sr 90.

  You will only need to use one of the scintillator/PMTs for this part of the experiment. Decide on how to best setup your cosmic telescope viz. discr setting and HV input from the calibration setup above.
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Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histogram the results. Your histogram will have on the horizontal axis the number of counts per interval and on the vertical axis the number of times you record a particular number of counts. How is the data distributed? Then repeat the exercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achieve these measurements. You can change the distance between the source and the scintillator or adjust the discriminator level. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe.

Part B: Cosmic Ray Flux

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Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histogram the results. Your histogram will have on the horizontal axis the number of counts per interval and on the vertical axis the number of times you record a particular number of counts. How is the data distributed? Then repeat the exercise twice setting the equipment up to now collect 10 events and repeat with 100 events per time interval. You can adjust any of the experimental conditions you control to achieve these measurements. You can change the distance between the source and the scintillator or adjust the discriminator level. Whatever you do make sure you retain the randomness of the events by ensuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe and compare it with the corresponding exercise in the Monte Carlo Lab where you essentially did the same thing on a computer, although with a significantly larger set of data.

Part C: Cosmic Ray Flux

 
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Using both PMTs, both of which you should have already plateaued and are running in optimal configuration for your experiment, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module inline between the discriminator outputs and the counter. The coincidence counter will trigger and output a NIM pulse when it detects two NIM pulses. This particular coincidence counter uses the size of the input pulse to select the size of the window it will use to determine if there is a coincidence, check the manual for the device if you are interested in details, something you'll have to find online. As you take data do plot the distribution. In the SLAC paper, linked below you'll see an estimate of the count rate. Make sure your count rate is consistent with your expectation. It typically takes 20 minutes to take one reading and you don't want take 10 of these 20 min reading to find out you did something wrong. and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See document from SLAC linked below.

Equipment:

>
>
Using both PMTs, both of which you should have already plateaued and are running in the optimal configuration for your experiment, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module inline between the discriminator outputs and the counter. The coincidence counter will trigger and output a NIM pulse when it detects two NIM pulses. This particular coincidence counter uses the size of the input pulse to select the size of the window used to determine whether a coincidence condition has been met. You can check the manual for the device if you are interested in details, something you'll have to find online. As you take data plot the distribution. In the SLAC paper, linked below you'll see an estimate of the count rate. Make sure your count rate is consistent with your expectation. You can take data for as long as you like but given the constraints, on class time I recommend taking data in 20-minute blocks per azimuthal angle. Also, plot the data as you take it. You do not want to take 10 measurements, each 20 minutes long, and then find that something is wrong with your data. In your report, your primary result is the histogram of counts vs. angle and the fit of your data to the expected distribution. In this lab finding that your data is consistent with the expected experimentally determined function is sufficient. We do not need to try to find or establish why it is distributed as a cos2. For that, we would need a lot more time and much more elaborate equipment. There is a nice write up on this part that you can access as a reference. See document from SLAC linked below.

Comments on the CRT apparatus:

 
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Our Cosmic Ray Telescope consists of a piece of plastic (organic) scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the transparent plastic material, reflecting from surfaces until eventually some of the photons emerge at the front face of the PMT. The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recorded by standard laboratory equipment. You should provide in your write up an a short description, longer than this, of how this works. You should also include a paragraph or two about cosmic rays, what are they where do they come from and what does our detector actually "see".
>
>
Our Cosmic Ray Telescope consists of a piece of plastic (organic) scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the transparent plastic material, reflecting from surfaces until eventually some of the photons emerge at the front face of the PMT. The PMT is an electronic device based on the photoelectric effect that first converts a small number of photons, into an amplified electrical signal sufficiently large to be easily recorded by standard laboratory equipment. You should provide in your write-up a short description, longer than this, of how this works. You should also include a paragraph or two about cosmic rays, what are they where do they come from and what does our detector actually "sees".
  The list of necessary equipment is:
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  • Scintillation counters each with its own PMT (Cosmic Ray Telescope: Note for this experiment you will need to use both counter)
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  • Scintillation counters each with its own PMT (Cosmic Ray Telescope: Note for this experiment you will need to use both counters)
 
  • High Voltage Supply (to power the PMT)
  • NIM module Discriminator (to decide whether the signal is a true PMT pulse and not noise)
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  • NIM module Linear Fan In Fan Out (this allows you to duplicate RF signals from the PMT and NIM modules
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  • NIM module Linear Fan In Fan-Out (this allows you to duplicate RF signals from the PMT and NIM modules
 
  • NIM module Counter/timer (to count the number of NIM output signals)
  • NIM module Quad Coincide (produces a NIM output when two signal arrive within an interval of time determined by module's internal logic)
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  • Oscilloscope (to examine the output of the PMT and help set discriminator levels etc.)
  • 90Sr radioactive source
Write Up
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Turning in your lab report

 
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Include in your introduction a breif description of the important components of the apparatus you used to conduct this experiment:
  1. The Scintillator: Look up references on how organic or plastic scintillators work. The scintillator you are using is I believe a Bicron BC 400 series plastic scintillator
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Because of the nature of this lab please provide an expanded introduction that includes the following elements. A few paragraphs, on the physics of cosmic rays, what are they where do they come from, etc. You can include some history if you wish but focus a little on the particle physics aspect, including the fact that what we see at sea level are mostly muons. What are these, briefly. In your introduction, you should also describe the operation of the various parts of the CRT. For example:
  1. The Scintillator: Look up references on how organic or plastic scintillators work. The scintillator you are using is a Bicron BC 400 series plastic scintillator
 
  1. The Photomultiplier: Describe how a PMT works. You should provide as much detail as you need to demonstrate that you understand how this device functions and why it is used.
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  1. The High Voltage supply, Just noting that one is used is probably sufficient.
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  1. The High Voltage supply, Just noting that one is used is sufficient.
 
  1. The data acquisition equipment: The various NIM modules you used in your experiment. You should be familiar with the operation of each and report on their use and function in your write up.
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  1. The Oscilloscope: No description required but you may want to explain who you used it.

Analysis

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Upload your lab report (article) to the Turnitin via the gray box under the "This tool needs to be loaded in a new browser window" line below. It will be graded along the rubric described in this page Grading Rubric. Read through the rubric carefully to maximize your score. If you have any questions please ask. Remember lab reports are usually due on Friday evening after you complete the experiment in class. If you have questions please ask.

Turning in your coding project

Please upload your code to the assignment Monte Carlo Project under the Python Coding Project group. Along with a grade for your report you will be graded separately on the coding sample you provide via upload. Here are important steps you should take to earn a good grade.

  1. Make sure each "Part" is in its own file. You can label your program as you wish as long as I can identify it when I run it.
  2. Make sure your program(s) run in the spyder IDE.
  3. Make sure your program is well commented as I will need to figure out what you did in order to evaluate the programming.
 
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Histogram your flux measurments, number of counts vs. angle w.r.t zenith and fit the distribution with an appropriate probability distribution funciton. Discuss the results and the goodness of fit.
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This tool needs to be loaded in a new browser window
  GradingRubric

Revision 102018-01-08 - JorgeRodriguez

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META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Cosmic Ray Lab

Revision 92014-08-26 - jrodrig

Line: 1 to 1
 
META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Cosmic Ray Lab

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In this lab you will measure the cosmic ray flux as a function of the zenith angle and determine its shape by fitting your data with a function that represent theoretical expectations. Does it conform to those expections?
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In this lab you will measure the cosmic ray flux as a function of the zenith angle and determine its shape by fitting your data with a function that represent theoretical expectations. Does it conform to those expectations?
 

Setup and calibration

Changed:
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Before you begin your flux measurements you should become familiar with the experimental apparatus. To do this we'll first perform a calibration of the Cosmic Telesope, basically determine what high voltage to use for the PMT input and then take measurments of count rates before we plunge into our flux measurements.
>
>
Before you begin your flux measurements you should become familiar with the experimental apparatus. To do this we'll first perform a calibration of the Cosmic Telescope, basically determine what high voltage to use for the PMT input and then take measurements of count rates before we plunge into our flux measurements.
 
Changed:
<
<
First: Connect the HV supply to the PMTs and use the oscilloscope to find the output signal from the PMT. You will likely need to adjust the time scale or sweep (horizontal axis) and the voltage scale (verticle axis) on the scope. We expect output signals from the PMT to be 10-20 ns long and the output voltage to be a few milivolts for the Cosmic Ray telescope setup. You'll also need to set up the scope to self trigger on the output pulse; set the trigger to trigger on the channel the PMT output is on. Note that the output will only trigger the scope if it exceeds a set discriminator (disc) threshold (the "level" knob located on the tigger portion of the scope). Adjust the level knob to some fraction of the PMT's average output voltage. Since our PMT output voltage is negative you'll want to set the threshold below 0 V to display any events.
>
>
First: Connect the HV supply to the PMTs and use the oscilloscope to find the output signal from the PMT. You will likely need to adjust the time scale or sweep (horizontal axis) and the voltage scale (vertical axis) on the scope. We expect output signals from the PMT to be 10-20 ns long and the output voltage to be a few millivolts for the Cosmic Ray telescope setup. You'll also need to set up the scope to self trigger on the output pulse; set the trigger to trigger on the channel the PMT output is on. Note that the output will only trigger the scope if it exceeds a set discriminator (disc) threshold (the "level" knob located on the trigger portion of the scope). Adjust the level knob to some fraction of the PMT's average output voltage. Since our PMT output voltage is negative you'll want to set the threshold below 0 V to display any events.
 
Changed:
<
<
Once you have your scope displaying multiple PMT pulses and have acertained a reasonable value for your discriminator threshold you can take the PMT output and redirect it to the discriminator NIM module. As with the disc threshold on the scope the disc threshold on the NIM Module is used to filter out noise pulses from signal pulses. You can adjust the disc threshold on the NIM module by turning the tiny set screw hidden inside the whole labled "THR". The threshold volatage can be read with a multimeter with leads connected to ground and the disc reading pad.
>
>
Once you have your scope displaying multiple PMT pulses and have ascertained a reasonable value for your discriminator threshold you can take the PMT output and redirect it to the discriminator NIM module. As with the disc threshold on the scope the disc threshold on the NIM Module is used to filter out noise pulses from signal pulses. You can adjust the disc threshold on the NIM module by turning the tiny set screw hidden inside the whole labeled "THR". The threshold voltage can be read with a multimeter with leads connected to ground and the disc reading pad.
 
Changed:
<
<
Before you proceed with the experiments, PART A and B below lets first determine the proper input volatage to run the PMTs at, given the chosen disc threshold settings that you've selected. We do this to insure that the PMT pulses and thus count rates are stable across a sizable range of input voltages which may drift over the course of the experinent. We'll do this by measuring the count rate as a function of input voltage and look the input voltage that corresponds to start of the count platue.
>
>
Before you proceed with the experiments, PART A and B below lets first determine the proper input voltage to run the PMTs at, given the chosen disc threshold settings that you've selected. We do this to insure that the PMT pulses and thus count rates are stable across a sizable range of input voltages which may drift over the course of the experiment. We'll do this by measuring the count rate as a function of input voltage and look the input voltage that corresponds to start of the count plateau.
 
Changed:
<
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Begin by setuping up the cosmic telescope by connecting the PMT output to the NIM discriminator then connect the disc output to the counter. Set the counter time window to collect a few 100 events. Make sure that you are counting real signals by insuring that the disc is set sufficiently high, check with the scope. Take count reading at variuos PMT input voltage and plot the results. Please DO NOT go beyond 2000 VOLTS. What you should see is that the count rates varies a lot when the voltage is set too high or too low. You'll want to use the a random event source, like the Sr 90 to insure you have real triggers instead of noise with proper disc setting. DO this for BOTH PMTs and provide in your lab report the plots you create.
>
>
Begin by setting up the cosmic telescope by connecting the PMT output to the NIM discriminator then connect the disc output to the counter. Set the counter time window to collect a few 100 events. Make sure that you are counting real signals by insuring that the disc is set sufficiently high, check with the scope. Take count reading at various PMT input voltage and plot the results. Please DO NOT go beyond 2000 VOLTS. What you should see is that the count rates varies a lot when the voltage is set too high or too low. You'll want to use the a random event source, like the Sr 90 to insure you have real triggers instead of noise with proper disc setting. DO this for BOTH PMTs and provide in your lab report the plots you create.
 

Part A: Observation of Poisson and Gaussian distributions in radioactive decay of Sr 90.

You will only need to use one of the scintillator/PMTs for this part of the experiment. Decide on how to best setup your cosmic telescope viz. discr setting and HV input from the calibration setup above.

Changed:
<
<
Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histrogram the results. Your histrogram will have on the horizontal axis the number of counts per interval and on the vertical axis the number of times you record a particular number of counts. How is the data distributed? Then repeat the excercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achive these measurements. You can change the distance between the source and the scintilator or adjust the discriminator level. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe.
>
>
Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histogram the results. Your histogram will have on the horizontal axis the number of counts per interval and on the vertical axis the number of times you record a particular number of counts. How is the data distributed? Then repeat the exercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achieve these measurements. You can change the distance between the source and the scintillator or adjust the discriminator level. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe.
 

Part B: Cosmic Ray Flux

Changed:
<
<
Using both PMTs, both of which you should have already platued and are running in optimal configuration for your experiment, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module inline between the discriminator outputs and the counter. The coincidence counter will trigger and output a NIM pulse when it detects two NIM pulses. This particular coincidence counter uses the size of the input pulse to select the size of the window it will use to detemine if there is a coincidence, check the manual for the device if you are interested in details, something you'll have to find online. As you take data do plot the distribution. In the slac paper, linked below you'll see an estimate of the count rate. Make sure your count rate is consistent with your expectation. It typically takes 20 minutes to take one reading and you don't want take 10 of these 20 min reading to find out you did something wrong. and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See document from slac linked below.
>
>
Using both PMTs, both of which you should have already plateaued and are running in optimal configuration for your experiment, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module inline between the discriminator outputs and the counter. The coincidence counter will trigger and output a NIM pulse when it detects two NIM pulses. This particular coincidence counter uses the size of the input pulse to select the size of the window it will use to determine if there is a coincidence, check the manual for the device if you are interested in details, something you'll have to find online. As you take data do plot the distribution. In the SLAC paper, linked below you'll see an estimate of the count rate. Make sure your count rate is consistent with your expectation. It typically takes 20 minutes to take one reading and you don't want take 10 of these 20 min reading to find out you did something wrong. and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See document from SLAC linked below.
 

Equipment:

Changed:
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Our Cosmic Ray Telescoe consists of a piece of plastic (organic Bicron BC 409) scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the transparent plastic material, reflecting from surfaces until eventually some of the photons emerge at the front face of the PMT. The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recored by standard laboratory equipment. You should provide in your writeup an a short description, longer than this, of how this works. You should also include a paragraph or two about cosmc rays, what are they where do they come from and what does our detector actually "see".
>
>
Our Cosmic Ray Telescope consists of a piece of plastic (organic) scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the transparent plastic material, reflecting from surfaces until eventually some of the photons emerge at the front face of the PMT. The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recorded by standard laboratory equipment. You should provide in your write up an a short description, longer than this, of how this works. You should also include a paragraph or two about cosmic rays, what are they where do they come from and what does our detector actually "see".
  The list of necessary equipment is:
  • Scintillation counters each with its own PMT (Cosmic Ray Telescope: Note for this experiment you will need to use both counter)
  • High Voltage Supply (to power the PMT)
  • NIM module Discriminator (to decide whether the signal is a true PMT pulse and not noise)
Changed:
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  • NIM module Linear Fan In Fan Out (this allows you to duplicate RF signals from the PMT and NIM moudules
>
>
  • NIM module Linear Fan In Fan Out (this allows you to duplicate RF signals from the PMT and NIM modules
 
  • NIM module Counter/timer (to count the number of NIM output signals)
  • NIM module Quad Coincide (produces a NIM output when two signal arrive within an interval of time determined by module's internal logic)
  • Oscilloscope (to examine the output of the PMT and help set discriminator levels etc.)
Line: 39 to 39
 Write Up

Include in your introduction a breif description of the important components of the apparatus you used to conduct this experiment:

Changed:
<
<
  1. The Scintillator: Look up references on how organic or plastic scintillators work. The scintillator you are using is I belive a Bicron BC 400 series plastic scintillator
>
>
  1. The Scintillator: Look up references on how organic or plastic scintillators work. The scintillator you are using is I believe a Bicron BC 400 series plastic scintillator
 
  1. The Photomultiplier: Describe how a PMT works. You should provide as much detail as you need to demonstrate that you understand how this device functions and why it is used.
  2. The High Voltage supply, Just noting that one is used is probably sufficient.
Changed:
<
<
  1. The data aquisition equipment: The various NIM modules you used in your experiment. You should be familiar with the operation of each and report on their use and function in your writeup.
>
>
  1. The data acquisition equipment: The various NIM modules you used in your experiment. You should be familiar with the operation of each and report on their use and function in your write up.
 
  1. The Oscilloscope: No description required but you may want to explain who you used it.

Analysis

Revision 82014-08-26 - jrodrig

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META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29
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Lab Assignment: Measure the angular distribution of cosmic ray flux

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Lab Assignment: Cosmic Ray Lab

  In this lab you will measure the cosmic ray flux as a function of the zenith angle and determine its shape by fitting your data with a function that represent theoretical expectations. Does it conform to those expections?

Setup and calibration

Before you begin your flux measurements you should become familiar with the experimental apparatus. To do this we'll first perform a calibration of the Cosmic Telesope, basically determine what high voltage to use for the PMT input and then take measurments of count rates before we plunge into our flux measurements.

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First: Connect the HV supply to the PMTs and use the oscilloscope to find the output signal from the PMT. You will likely need to adjust the time scale or sweep (horizontal axis) and the voltage scale (verticle axis) on the scope. We expect output signals from the PMT to be 10-20 ns long and the output voltage to be a few milivolts for this Cosmic Ray telescope setup. You'll also need to set up the scope to self trigger on the out pulse; that is set the trigger channel to the channel in which you've pulgged the PMT output. The scope also has a discriminator threshold (the "level" knob located on the tigger portion of the scope.). You will need to adjust that to some fraction of the PMT's average output voltage. Since our PMT output voltage is negative you'll want to set the threshold below 0 V to display any events.
>
>
First: Connect the HV supply to the PMTs and use the oscilloscope to find the output signal from the PMT. You will likely need to adjust the time scale or sweep (horizontal axis) and the voltage scale (verticle axis) on the scope. We expect output signals from the PMT to be 10-20 ns long and the output voltage to be a few milivolts for the Cosmic Ray telescope setup. You'll also need to set up the scope to self trigger on the output pulse; set the trigger to trigger on the channel the PMT output is on. Note that the output will only trigger the scope if it exceeds a set discriminator (disc) threshold (the "level" knob located on the tigger portion of the scope). Adjust the level knob to some fraction of the PMT's average output voltage. Since our PMT output voltage is negative you'll want to set the threshold below 0 V to display any events.
 
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Once you have your scope displaying multiple PMT pulses and have acertained a reasonable value for your discriminator threshold you can take the PMT output and redirect it to the discriminator NIM module. As with the disc threshold on the scope the disc threshold on the NIM Module is used to filter out noise pulses from signal pulses. You can adjust the disc threshold on the NIM module by turning the tiny set screw hidden inside the whole labled "THR". The threshold volatage can be read with multimeter.
>
>
Once you have your scope displaying multiple PMT pulses and have acertained a reasonable value for your discriminator threshold you can take the PMT output and redirect it to the discriminator NIM module. As with the disc threshold on the scope the disc threshold on the NIM Module is used to filter out noise pulses from signal pulses. You can adjust the disc threshold on the NIM module by turning the tiny set screw hidden inside the whole labled "THR". The threshold volatage can be read with a multimeter with leads connected to ground and the disc reading pad.
 
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Before you proceed with the experiments, PART A and B below lets determine the proper volatage to input into the PMTs given the disc threshold. We do this because you want to run your PMTs, each an individual with, even if manufactured identically, can have different optimal operating voltages which can vary over time.
>
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Before you proceed with the experiments, PART A and B below lets first determine the proper input volatage to run the PMTs at, given the chosen disc threshold settings that you've selected. We do this to insure that the PMT pulses and thus count rates are stable across a sizable range of input voltages which may drift over the course of the experinent. We'll do this by measuring the count rate as a function of input voltage and look the input voltage that corresponds to start of the count platue.
 
Changed:
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The best way to determine the operating voltage of your setup is to basically check to see that the count rate, given disc threshold setting and PMT input voltage, varies little over a set of input voltages. This process is sometime referred to as "Platue the PMTs", although here its not just the PMT that are involved. To do this setup up your cosmic telescope by connecting the PMT output to the NIM discriminator then connect the disc output to the counter. Setup the counter so as to collect events over a time window to collect a few 100 events and then vary the input voltage and record the counts. I would vary the voltage by 100 volts starting at around 1000 volts. Do not go beyond 2000 volts please. What you should see is the number of counts varies a lot when the voltage is set too high or too low. You'll want to use the a random event source, like the Sr 90 to insure you have real triggers instead of noise. DO this for BOTH PMTs and provide in your lab report the plots you make. Unfortunately you have a single HV power supply that can only ou

PART A

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Begin by setuping up the cosmic telescope by connecting the PMT output to the NIM discriminator then connect the disc output to the counter. Set the counter time window to collect a few 100 events. Make sure that you are counting real signals by insuring that the disc is set sufficiently high, check with the scope. Take count reading at variuos PMT input voltage and plot the results. Please DO NOT go beyond 2000 VOLTS. What you should see is that the count rates varies a lot when the voltage is set too high or too low. You'll want to use the a random event source, like the Sr 90 to insure you have real triggers instead of noise with proper disc setting. DO this for BOTH PMTs and provide in your lab report the plots you create.

Part A: Observation of Poisson and Gaussian distributions in radioactive decay of Sr 90.

  You will only need to use one of the scintillator/PMTs for this part of the experiment. Decide on how to best setup your cosmic telescope viz. discr setting and HV input from the calibration setup above.

Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histrogram the results. Your histrogram will have on the horizontal axis the number of counts per interval and on the vertical axis the number of times you record a particular number of counts. How is the data distributed? Then repeat the excercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achive these measurements. You can change the distance between the source and the scintilator or adjust the discriminator level. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe.

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Part B

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Part B: Cosmic Ray Flux

  Using both PMTs, both of which you should have already platued and are running in optimal configuration for your experiment, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module inline between the discriminator outputs and the counter. The coincidence counter will trigger and output a NIM pulse when it detects two NIM pulses. This particular coincidence counter uses the size of the input pulse to select the size of the window it will use to detemine if there is a coincidence, check the manual for the device if you are interested in details, something you'll have to find online. As you take data do plot the distribution. In the slac paper, linked below you'll see an estimate of the count rate. Make sure your count rate is consistent with your expectation. It typically takes 20 minutes to take one reading and you don't want take 10 of these 20 min reading to find out you did something wrong. and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See document from slac linked below.

Equipment:

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To count the number of decays of the radioactive source you will need to setup equipment that can detect the emission of electrons in this energy range. You will use the cosmic ray telescope in the lab for the dection of the electrons. Basically the telescope consists of a piece of plastic scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the plastic material, designed to be transparent to the emitted light, reflecting from surfaces, colliding with other electrons etc, some of the photons end up at the front of the photomultiplier tube (PMT). The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recored by standard laboratory equipment. You should provide in your writeup an a short description of how the emitted electrons are detected by the equipment you use in this experiment.
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Our Cosmic Ray Telescoe consists of a piece of plastic (organic Bicron BC 409) scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the transparent plastic material, reflecting from surfaces until eventually some of the photons emerge at the front face of the PMT. The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recored by standard laboratory equipment. You should provide in your writeup an a short description, longer than this, of how this works. You should also include a paragraph or two about cosmc rays, what are they where do they come from and what does our detector actually "see".
  The list of necessary equipment is:
  • Scintillation counters each with its own PMT (Cosmic Ray Telescope: Note for this experiment you will need to use both counter)

Revision 72014-04-10 - jrodrig

Line: 1 to 1
 
META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Measure the angular distribution of cosmic ray flux

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In this lab you will measure the cosmic ray flux as a function of zenith angle and determine the shape of the distribtiuon of your data. Does it conform with expections?
>
>
In this lab you will measure the cosmic ray flux as a function of the zenith angle and determine its shape by fitting your data with a function that represent theoretical expectations. Does it conform to those expections?
 

Setup and calibration

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Before you begin your flux measurements you should get familiar with the experimental apparatus. Connect the HV supply to the PMTs and use the scope to find the PMT pulse from the output on the PMT. Note that to see the PMT signal you'll need to adjust scope's time scale (horizontal axis) voltage scales (verticle axis). Singal pulses for the PMTs we use in this lab are a few less than 10 ns long. The output voltage should be a few milivolts. You'll also need to set up the scope to trigger the pulse that comes from the PMT, so set the trigger to channel 1 or whatever channel your PMT out is connected to. The scope also has a discriminator threshold (the level knob located on the tigger portion of your scope.). You will need to adjust that to some fraction of the PMT pulse's max voltage. Note that the PMTs in our cosmic ray experiment produce negative output voltages.
>
>
Before you begin your flux measurements you should become familiar with the experimental apparatus. To do this we'll first perform a calibration of the Cosmic Telesope, basically determine what high voltage to use for the PMT input and then take measurments of count rates before we plunge into our flux measurements.
 
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Once you've established a PMT pulse setup the experiemnt to take data by connecting the PMT signal to the NIM counter/timer through the NIM discriminator. The discriminator threshold on the NIM Module is used to filter out noise pulses that can contaminate your results. A source of actual random processes like a radioactive source is useful here. We provide you with several in the lab. Here you can use one of the 90 Sr buttons locked in the cabinet.
>
>
First: Connect the HV supply to the PMTs and use the oscilloscope to find the output signal from the PMT. You will likely need to adjust the time scale or sweep (horizontal axis) and the voltage scale (verticle axis) on the scope. We expect output signals from the PMT to be 10-20 ns long and the output voltage to be a few milivolts for this Cosmic Ray telescope setup. You'll also need to set up the scope to self trigger on the out pulse; that is set the trigger channel to the channel in which you've pulgged the PMT output. The scope also has a discriminator threshold (the "level" knob located on the tigger portion of the scope.). You will need to adjust that to some fraction of the PMT's average output voltage. Since our PMT output voltage is negative you'll want to set the threshold below 0 V to display any events.
 
Changed:
<
<
To determine the operating voltage of each PMT you'll need to "Platue the PMTs". What you do here is simply record the PMT count rate as a function of input voltage, starting at say 1000 volts. PMTs are all different and they can change over time so its a good practice to do this operation before you use any PMT for the first. Setup the apparatus to count the number of event (aka triggers) for some interval of time and then vary the PMT input voltage and record what you measure. Since the count rate will depend on discriminatory threshold you will need to pick a reasonable value. As to what is a reasonable value you'll need to figure this out on your own. For example, check the pulses with scope and see if you can guess at a reasonable value to set your disc to. Set your PMT's input voltage and determine the count the rate (probably better to use a source to get a reasonable count rate in a short amount of time) next increase the voltage by say 100 Volts intervals, repeat a few starting at 1000V input vPlot the results and the somewhere in the middle of the platue is where you want to run your PMT during the experiment. Make sure you use a random event source to insure you have real triggers instead of noise. DO BOTH PMTs, unfortunately you have a HV power supply that can only ou
>
>
Once you have your scope displaying multiple PMT pulses and have acertained a reasonable value for your discriminator threshold you can take the PMT output and redirect it to the discriminator NIM module. As with the disc threshold on the scope the disc threshold on the NIM Module is used to filter out noise pulses from signal pulses. You can adjust the disc threshold on the NIM module by turning the tiny set screw hidden inside the whole labled "THR". The threshold volatage can be read with multimeter.

Before you proceed with the experiments, PART A and B below lets determine the proper volatage to input into the PMTs given the disc threshold. We do this because you want to run your PMTs, each an individual with, even if manufactured identically, can have different optimal operating voltages which can vary over time.

The best way to determine the operating voltage of your setup is to basically check to see that the count rate, given disc threshold setting and PMT input voltage, varies little over a set of input voltages. This process is sometime referred to as "Platue the PMTs", although here its not just the PMT that are involved. To do this setup up your cosmic telescope by connecting the PMT output to the NIM discriminator then connect the disc output to the counter. Setup the counter so as to collect events over a time window to collect a few 100 events and then vary the input voltage and record the counts. I would vary the voltage by 100 volts starting at around 1000 volts. Do not go beyond 2000 volts please. What you should see is the number of counts varies a lot when the voltage is set too high or too low. You'll want to use the a random event source, like the Sr 90 to insure you have real triggers instead of noise. DO this for BOTH PMTs and provide in your lab report the plots you make. Unfortunately you have a single HV power supply that can only ou

 

PART A

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You will only need to use one of the scintillator/PMTs for this part of the experiment.
>
>
You will only need to use one of the scintillator/PMTs for this part of the experiment. Decide on how to best setup your cosmic telescope viz. discr setting and HV input from the calibration setup above.
 
Changed:
<
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Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histrogram the results. How is the data distributed? Then repeat the excercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achive these measurements. You can change the distance between the source and the scintilator or adjust the discriminator levels. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe.
>
>
Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histrogram the results. Your histrogram will have on the horizontal axis the number of counts per interval and on the vertical axis the number of times you record a particular number of counts. How is the data distributed? Then repeat the excercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achive these measurements. You can change the distance between the source and the scintilator or adjust the discriminator level. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe.
 

Part B

Using both PMTs, both of which you should have already platued and are running in optimal configuration for your experiment, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module inline between the discriminator outputs and the counter. The coincidence counter will trigger and output a NIM pulse when it detects two NIM pulses. This particular coincidence counter uses the size of the input pulse to select the size of the window it will use to detemine if there is a coincidence, check the manual for the device if you are interested in details, something you'll have to find online. As you take data do plot the distribution. In the slac paper, linked below you'll see an estimate of the count rate. Make sure your count rate is consistent with your expectation. It typically takes 20 minutes to take one reading and you don't want take 10 of these 20 min reading to find out you did something wrong. and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See document from slac linked below.

Revision 62014-03-29 - jrodrig

Line: 1 to 1
 
META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Measure the angular distribution of cosmic ray flux

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  • NIM module Quad Coincide (produces a NIM output when two signal arrive within an interval of time determined by module's internal logic)
  • Oscilloscope (to examine the output of the PMT and help set discriminator levels etc.)
  • 90Sr radioactive source
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When writing up the lab you should include a breif description of the important parts of this experiment:
  1. The Scintillator: Look up references on how organic or plastic scintillators work.
  2. The Photomultiplier: Describe the funciton of the photo cathode and the amplifier, why do you need such a high voltage.
  3. The High Voltage supply: Just note that there is one.
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Write Up

Include in your introduction a breif description of the important components of the apparatus you used to conduct this experiment:

  1. The Scintillator: Look up references on how organic or plastic scintillators work. The scintillator you are using is I belive a Bicron BC 400 series plastic scintillator
  2. The Photomultiplier: Describe how a PMT works. You should provide as much detail as you need to demonstrate that you understand how this device functions and why it is used.
  3. The High Voltage supply, Just noting that one is used is probably sufficient.
 
  1. The data aquisition equipment: The various NIM modules you used in your experiment. You should be familiar with the operation of each and report on their use and function in your writeup.
  2. The Oscilloscope: No description required but you may want to explain who you used it.
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Write Up

 

Analysis

Histogram your flux measurments, number of counts vs. angle w.r.t zenith and fit the distribution with an appropriate probability distribution funciton. Discuss the results and the goodness of fit.

Revision 52014-03-27 - jrodrig

Line: 1 to 1
 
META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Measure the angular distribution of cosmic ray flux

Changed:
<
<
Basically you will measure the cosmic ray flux as a function of zenith angle and determine the shape of the distribtiuon of your data. Does it conform with expections? it with
>
>
In this lab you will measure the cosmic ray flux as a function of zenith angle and determine the shape of the distribtiuon of your data. Does it conform with expections?
 

Setup and calibration

Changed:
<
<
Before you begin your flux measurements you should become familiar with the experimental apparatus. Connect the HV supply to the PMTs and use the scope to find the PMT pulse from the output on the PMT. Note that to see the PMT signal you'll need to fiddle with the time vs voltage scales accordingly. Singal pulses for the PMTs in this lab are typically a few less than 10 ns long. The output voltage is a few milivolts. You'll also need to set up the scope to trigger on the very same PMT pulse, self triggered. The scope also has a discriminator threshold (level) which you'll need to adjust to some fraction of the PMT pulse's max voltage. Note that the PMTs in our cosmic ray experiment are negative.
>
>
Before you begin your flux measurements you should get familiar with the experimental apparatus. Connect the HV supply to the PMTs and use the scope to find the PMT pulse from the output on the PMT. Note that to see the PMT signal you'll need to adjust scope's time scale (horizontal axis) voltage scales (verticle axis). Singal pulses for the PMTs we use in this lab are a few less than 10 ns long. The output voltage should be a few milivolts. You'll also need to set up the scope to trigger the pulse that comes from the PMT, so set the trigger to channel 1 or whatever channel your PMT out is connected to. The scope also has a discriminator threshold (the level knob located on the tigger portion of your scope.). You will need to adjust that to some fraction of the PMT pulse's max voltage. Note that the PMTs in our cosmic ray experiment produce negative output voltages.
 
Changed:
<
<
Once you've established a PMT pulse setup the experiemnt to take data by connecting the PMT signal to the NIM counter/timer through the NIM discriminator. The discriminator threshold is used to filter out noise pulses that can contaminate your results. A source of actual random processes like a radioactive source is useful here. We provide you with several in the lab. Here you'll use 90 Sr.
>
>
Once you've established a PMT pulse setup the experiemnt to take data by connecting the PMT signal to the NIM counter/timer through the NIM discriminator. The discriminator threshold on the NIM Module is used to filter out noise pulses that can contaminate your results. A source of actual random processes like a radioactive source is useful here. We provide you with several in the lab. Here you can use one of the 90 Sr buttons locked in the cabinet.
 
Changed:
<
<
To determine the operating voltage of each PMT you'll need to "Platue the PMTs". What you do here is simply record the PMT count rate as a function of input voltage, starting at say 1000 volts. PMTs are all different and they can change over time so its a good practice to do this operation before you use any PMT for the first. Setup the apparatus to count the number of event (aka triggers) for some interval of time and then vary the PMT input voltage and record what you measure. Plot the results and the somewhere in the middle of the platue is where you want to run your PMT during the experiment. Make sure you use a random event source to insure you have real triggers instead of noise.
>
>
To determine the operating voltage of each PMT you'll need to "Platue the PMTs". What you do here is simply record the PMT count rate as a function of input voltage, starting at say 1000 volts. PMTs are all different and they can change over time so its a good practice to do this operation before you use any PMT for the first. Setup the apparatus to count the number of event (aka triggers) for some interval of time and then vary the PMT input voltage and record what you measure. Since the count rate will depend on discriminatory threshold you will need to pick a reasonable value. As to what is a reasonable value you'll need to figure this out on your own. For example, check the pulses with scope and see if you can guess at a reasonable value to set your disc to. Set your PMT's input voltage and determine the count the rate (probably better to use a source to get a reasonable count rate in a short amount of time) next increase the voltage by say 100 Volts intervals, repeat a few starting at 1000V input vPlot the results and the somewhere in the middle of the platue is where you want to run your PMT during the experiment. Make sure you use a random event source to insure you have real triggers instead of noise. DO BOTH PMTs, unfortunately you have a HV power supply that can only ou
 

PART A

You will only need to use one of the scintillator/PMTs for this part of the experiment.

Changed:
<
<
Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histrogram the results. How is the data distributed? Then repeat the excercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achive these measurements. You can change the distance between the source and the scintilator or adjust the discriminator levels. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise.
>
>
Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histrogram the results. How is the data distributed? Then repeat the excercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achive these measurements. You can change the distance between the source and the scintilator or adjust the discriminator levels. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise. There is no need to fit the distributions in this part of the lab but please do feel free to comment on what you observe.
 

Part B

Changed:
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Using both PMTs, both of which you should have already platued, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module to record when the two PMTs fire within a couple of ns of each other. Plot the distribution and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See
>
>
Using both PMTs, both of which you should have already platued and are running in optimal configuration for your experiment, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module inline between the discriminator outputs and the counter. The coincidence counter will trigger and output a NIM pulse when it detects two NIM pulses. This particular coincidence counter uses the size of the input pulse to select the size of the window it will use to detemine if there is a coincidence, check the manual for the device if you are interested in details, something you'll have to find online. As you take data do plot the distribution. In the slac paper, linked below you'll see an estimate of the count rate. Make sure your count rate is consistent with your expectation. It typically takes 20 minutes to take one reading and you don't want take 10 of these 20 min reading to find out you did something wrong. and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See document from slac linked below.
 

Equipment:

To count the number of decays of the radioactive source you will need to setup equipment that can detect the emission of electrons in this energy range. You will use the cosmic ray telescope in the lab for the dection of the electrons. Basically the telescope consists of a piece of plastic scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the plastic material, designed to be transparent to the emitted light, reflecting from surfaces, colliding with other electrons etc, some of the photons end up at the front of the photomultiplier tube (PMT). The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recored by standard laboratory equipment. You should provide in your writeup an a short description of how the emitted electrons are detected by the equipment you use in this experiment.

Revision 42014-02-25 - jrodrig

Line: 1 to 1
 
META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Measure the angular distribution of cosmic ray flux

Line: 10 to 10
  Once you've established a PMT pulse setup the experiemnt to take data by connecting the PMT signal to the NIM counter/timer through the NIM discriminator. The discriminator threshold is used to filter out noise pulses that can contaminate your results. A source of actual random processes like a radioactive source is useful here. We provide you with several in the lab. Here you'll use 90 Sr.
Changed:
<
<
To determine the operating voltage of each PMT you'll need to "Platue the PMTs". What you do here is simply record the PMT count rate as a function of input voltage, starting at say 1000 volts. PMTs are all different and they can change over time so its a good practice to do this operation before you use any PMT for the first. Setup the apparatus to count the number of triggers for some interval of time and then vary the PMT input voltage and record what you measure. Plot the results and the somewhere in the middle of the platue is where you want to run your PMT during the experiment. Make sure you use a random event source to insure you have real triggers instead of noise.
>
>
To determine the operating voltage of each PMT you'll need to "Platue the PMTs". What you do here is simply record the PMT count rate as a function of input voltage, starting at say 1000 volts. PMTs are all different and they can change over time so its a good practice to do this operation before you use any PMT for the first. Setup the apparatus to count the number of event (aka triggers) for some interval of time and then vary the PMT input voltage and record what you measure. Plot the results and the somewhere in the middle of the platue is where you want to run your PMT during the experiment. Make sure you use a random event source to insure you have real triggers instead of noise.
 

PART A

You will only need to use one of the scintillator/PMTs for this part of the experiment.

Revision 32013-10-31 - jrodrig

Line: 1 to 1
 
META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Measure the angular distribution of cosmic ray flux

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 Histogram your flux measurments, number of counts vs. angle w.r.t zenith and fit the distribution with an appropriate probability distribution funciton. Discuss the results and the goodness of fit.

GradingRubric

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META FILEATTACHMENT attachment="slac-tn-95-001.pdf" attr="" comment="SLAC Cosmic Ray Telescope paper" date="1383240102" name="slac-tn-95-001.pdf" path="slac-tn-95-001.pdf" size="3334317" user="jrodrig" version="1"

Revision 22013-10-29 - jrodrig

Line: 1 to 1
 
META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29
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Lab Assignment: Statistics of Random events

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Lab Assignment: Measure the angular distribution of cosmic ray flux

 
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In this lab the goal is to explore the statistics of random events. The events will this time be generated by a physical process that is random in nature, namely the radioactive decay of a sample of 90Sr. Strontium 90 is a rare isotope of Strontium, is a beta emitter (e-) and has a half life of 28.9 years. The relatively long lifetime will insure a "steady-state decay rate" that remains constant over the time scale of the lab and thus provide you with random sample of events to count.

Assignment: Is the Rate a Poisson or Gaussian Statistic?

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>
Basically you will measure the cosmic ray flux as a function of zenith angle and determine the shape of the distribtiuon of your data. Does it conform with expections? it with

Setup and calibration

 
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In this experiment you will do three sets of 100 measurements for the beta decay rate of 90Sr. You will then determine the mean rate by fitting your data to the appropriate distribution, either a Poisson and Gaussian.
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Before you begin your flux measurements you should become familiar with the experimental apparatus. Connect the HV supply to the PMTs and use the scope to find the PMT pulse from the output on the PMT. Note that to see the PMT signal you'll need to fiddle with the time vs voltage scales accordingly. Singal pulses for the PMTs in this lab are typically a few less than 10 ns long. The output voltage is a few milivolts. You'll also need to set up the scope to trigger on the very same PMT pulse, self triggered. The scope also has a discriminator threshold (level) which you'll need to adjust to some fraction of the PMT pulse's max voltage. Note that the PMTs in our cosmic ray experiment are negative.
 
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The experiment should be setup to record events at three different rates over a given time interval. To do this set up the counter/timer to record counts in 1 second interval with rates determined by the height of the source.
  • First adjust the height of source so that your rate is about 1 Hz. Make about a 100 measurements with this arrangement. (Note that the cosmic backgroud rate is of order 1 Hz but this is OK since this background rate is uncorrelated with the source rate.
  • Repeat the experiment but now position the source so that the rate increase to about 10 Hz.
  • Repeat the experiment this time with the rate adjusted to about 100 Hz.
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Once you've established a PMT pulse setup the experiemnt to take data by connecting the PMT signal to the NIM counter/timer through the NIM discriminator. The discriminator threshold is used to filter out noise pulses that can contaminate your results. A source of actual random processes like a radioactive source is useful here. We provide you with several in the lab. Here you'll use 90 Sr.

To determine the operating voltage of each PMT you'll need to "Platue the PMTs". What you do here is simply record the PMT count rate as a function of input voltage, starting at say 1000 volts. PMTs are all different and they can change over time so its a good practice to do this operation before you use any PMT for the first. Setup the apparatus to count the number of triggers for some interval of time and then vary the PMT input voltage and record what you measure. Plot the results and the somewhere in the middle of the platue is where you want to run your PMT during the experiment. Make sure you use a random event source to insure you have real triggers instead of noise.

PART A

You will only need to use one of the scintillator/PMTs for this part of the experiment.

Using a random source, that 90 Sr is as good a random source as any. Take 100 measurements with the count time interval set to collect on average 1 event per time interval. Histrogram the results. How is the data distributed? Then repeat the excercise but now use 100 events per time interval. You can adjust any of the experimental conditions you control to achive these measurements. You can change the distance between the source and the scintilator or adjust the discriminator levels. What ever you do make sure you retain the randomness of the events by insuring you are not picking up PMT or other sources of noise.

Part B

Using both PMTs, both of which you should have already platued, perform the flux vs. angle measurement. Here you'll need to use the coincide NIM module to record when the two PMTs fire within a couple of ns of each other. Plot the distribution and fit a function form to your data and discuss what you see. There is a nice write up on this part that you can access as a reference. See

 

Equipment:

To count the number of decays of the radioactive source you will need to setup equipment that can detect the emission of electrons in this energy range. You will use the cosmic ray telescope in the lab for the dection of the electrons. Basically the telescope consists of a piece of plastic scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the plastic material, designed to be transparent to the emitted light, reflecting from surfaces, colliding with other electrons etc, some of the photons end up at the front of the photomultiplier tube (PMT). The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recored by standard laboratory equipment. You should provide in your writeup an a short description of how the emitted electrons are detected by the equipment you use in this experiment.

The list of necessary equipment is:

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  • Scintillation counter with PMT (Cosmic Ray Telescope: Note you may not need to the second counter in this experiment)
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  • Scintillation counters each with its own PMT (Cosmic Ray Telescope: Note for this experiment you will need to use both counter)
 
  • High Voltage Supply (to power the PMT)
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  • Discriminator (to decide whether the signal is a true PMT pulse and not noise)
  • Counter/timer (to count the number of real PMT signals)
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  • NIM module Discriminator (to decide whether the signal is a true PMT pulse and not noise)
  • NIM module Linear Fan In Fan Out (this allows you to duplicate RF signals from the PMT and NIM moudules
  • NIM module Counter/timer (to count the number of NIM output signals)
  • NIM module Quad Coincide (produces a NIM output when two signal arrive within an interval of time determined by module's internal logic)
 
  • Oscilloscope (to examine the output of the PMT and help set discriminator levels etc.)
  • 90Sr radioactive source
When writing up the lab you should include a breif description of the important parts of this experiment:
  1. The Scintillator: Look up references on how organic or plastic scintillators work.
  2. The Photomultiplier: Describe the funciton of the photo cathode and the amplifier, why do you need such a high voltage.
  3. The High Voltage supply: Just note that there is one.
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  1. The data aquisition equipment: The signal from the Photo tube goes into a NIM (Nuclear Instrument Module) discriminator who function and operation you should understand and a rate counter.
  2. The Oscilloscope: No description required.
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  1. The data aquisition equipment: The various NIM modules you used in your experiment. You should be familiar with the operation of each and report on their use and function in your writeup.
  2. The Oscilloscope: No description required but you may want to explain who you used it.
 

Write Up

Analysis

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As with the MonteCarloLab you will need to histogram your data and then perform a fit to determine the mean rate and standard deviation. The histogram should include
  • On the horizontal "x" axis: the random variable in this case is the the rate or number of counts per unit time.
  • On the vertical "y" axis: the dependent variable or number of times the rate has a particular "x" value.
  • The total number of entries in your histogram should be all 100 of your trails.
Once you have your histograms, one for each of sets of data, you will need to fit it to a Gaussian and a Poisson distribution seperately. The fits determine the mean and width or standard deviations of the functional forms. You then compare the two fits and use a "goodness of fit" estimator to establish which function is the best fit. One such estimator is the normalized chi-squared "χ2/ν" where ν is the number of bin minus the number of parameters in the fit. The Gaussian fits can be done in MN_FIT as before, but you will have to do more work with the Poisson fits since MN_FIT doesn't have a Poisson function internally defined. You can do one of two things:
  1. You can can either create your own Possion function and use the MN_FIT/MINUIT framework to fit your data. This isn't too hard but you'll need to write a FORTRAN function and feed it to MN_FIT. There is a COMIS feature in MN_FIT the allows the users to create ther own fitting functions, (see help comis in MN_FIT) if you want to give this a spin I can help you set it up.
  2. You can do the Poisson fit by hand. This shouldn't be to difficult to do given that the function is discrete and when the rates "x" are small x! isn't too large a number for your calculator. Even for large x a recursion relation exists to help you out. Please refer to Dr. Raue's note. With this method you will, of course need to compute the the χ2/ν by hand as well, see Dr. Raue's chi-2 note.
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Histogram your flux measurments, number of counts vs. angle w.r.t zenith and fit the distribution with an appropriate probability distribution funciton. Discuss the results and the goodness of fit.
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META TOPICPARENT name="PHY4821L"
-- JorgeRodriguez - 2013-10-29

Lab Assignment: Statistics of Random events

In this lab the goal is to explore the statistics of random events. The events will this time be generated by a physical process that is random in nature, namely the radioactive decay of a sample of 90Sr. Strontium 90 is a rare isotope of Strontium, is a beta emitter (e-) and has a half life of 28.9 years. The relatively long lifetime will insure a "steady-state decay rate" that remains constant over the time scale of the lab and thus provide you with random sample of events to count.

Assignment: Is the Rate a Poisson or Gaussian Statistic?

In this experiment you will do three sets of 100 measurements for the beta decay rate of 90Sr. You will then determine the mean rate by fitting your data to the appropriate distribution, either a Poisson and Gaussian.

The experiment should be setup to record events at three different rates over a given time interval. To do this set up the counter/timer to record counts in 1 second interval with rates determined by the height of the source.

  • First adjust the height of source so that your rate is about 1 Hz. Make about a 100 measurements with this arrangement. (Note that the cosmic backgroud rate is of order 1 Hz but this is OK since this background rate is uncorrelated with the source rate.
  • Repeat the experiment but now position the source so that the rate increase to about 10 Hz.
  • Repeat the experiment this time with the rate adjusted to about 100 Hz.

Equipment:

To count the number of decays of the radioactive source you will need to setup equipment that can detect the emission of electrons in this energy range. You will use the cosmic ray telescope in the lab for the dection of the electrons. Basically the telescope consists of a piece of plastic scintillator made out of material that when exposed to charged particles reacts by emitting light. The light travels through the plastic material, designed to be transparent to the emitted light, reflecting from surfaces, colliding with other electrons etc, some of the photons end up at the front of the photomultiplier tube (PMT). The PMT is an electronic device based on the photoelectric effect that first converts a small number photons, into an amplified electrical signal sufficiently large to be easily recored by standard laboratory equipment. You should provide in your writeup an a short description of how the emitted electrons are detected by the equipment you use in this experiment.

The list of necessary equipment is:

  • Scintillation counter with PMT (Cosmic Ray Telescope: Note you may not need to the second counter in this experiment)
  • High Voltage Supply (to power the PMT)
  • Discriminator (to decide whether the signal is a true PMT pulse and not noise)
  • Counter/timer (to count the number of real PMT signals)
  • Oscilloscope (to examine the output of the PMT and help set discriminator levels etc.)
  • 90Sr radioactive source
When writing up the lab you should include a breif description of the important parts of this experiment:
  1. The Scintillator: Look up references on how organic or plastic scintillators work.
  2. The Photomultiplier: Describe the funciton of the photo cathode and the amplifier, why do you need such a high voltage.
  3. The High Voltage supply: Just note that there is one.
  4. The data aquisition equipment: The signal from the Photo tube goes into a NIM (Nuclear Instrument Module) discriminator who function and operation you should understand and a rate counter.
  5. The Oscilloscope: No description required.

Write Up

Analysis

As with the MonteCarloLab you will need to histogram your data and then perform a fit to determine the mean rate and standard deviation. The histogram should include

  • On the horizontal "x" axis: the random variable in this case is the the rate or number of counts per unit time.
  • On the vertical "y" axis: the dependent variable or number of times the rate has a particular "x" value.
  • The total number of entries in your histogram should be all 100 of your trails.
Once you have your histograms, one for each of sets of data, you will need to fit it to a Gaussian and a Poisson distribution seperately. The fits determine the mean and width or standard deviations of the functional forms. You then compare the two fits and use a "goodness of fit" estimator to establish which function is the best fit. One such estimator is the normalized chi-squared "χ2/ν" where ν is the number of bin minus the number of parameters in the fit. The Gaussian fits can be done in MN_FIT as before, but you will have to do more work with the Poisson fits since MN_FIT doesn't have a Poisson function internally defined. You can do one of two things:
  1. You can can either create your own Possion function and use the MN_FIT/MINUIT framework to fit your data. This isn't too hard but you'll need to write a FORTRAN function and feed it to MN_FIT. There is a COMIS feature in MN_FIT the allows the users to create ther own fitting functions, (see help comis in MN_FIT) if you want to give this a spin I can help you set it up.
  2. You can do the Poisson fit by hand. This shouldn't be to difficult to do given that the function is discrete and when the rates "x" are small x! isn't too large a number for your calculator. Even for large x a recursion relation exists to help you out. Please refer to Dr. Raue's note. With this method you will, of course need to compute the the χ2/ν by hand as well, see Dr. Raue's chi-2 note.
GradingRubric
 
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