Download - Temperature Effects on SCD Output
![Page 1: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/1.jpg)
Temperature Effects on SCD Output
Shawn Rosofsky
February 4, 2016
![Page 2: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/2.jpg)
2
Goal
• Analyze SCD data taken from Goddard thermal vacuum test• Determine the amount of the SCD output changes due to a
change in temperature• This analysis will later be used to help determine how often
to take the pedestal run
Temperature Effects on SCD Output Shawn Rosofsky, UMD
![Page 3: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/3.jpg)
3
Relevant Parameters
• SCD– SCD1
• Temperature– SCD Ladder Temperature– Refers to ladder 7 unless otherwise
stated
• Input– SCD has 24 ladders of channels with
its own temperature– Within a ladder groups of 16
channels share similar response patterns
– Total 2640 active channels out of a possible 2944 channels
– 2192 with working temperature sensors
• Output– SCD mean pedestal value for each
channel
Temperature Effects on SCD Output Shawn Rosofsky, UMD
SCD1
SCD Ladder2
![Page 4: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/4.jpg)
4
Raw Data Output of SCD1
Temperature Effects on SCD Output Shawn Rosofsky, UMD
![Page 5: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/5.jpg)
5
Sample from Each Channels Group of SCD1
Temperature Effects on SCD Output Shawn Rosofsky, UMD
![Page 6: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/6.jpg)
7
Channel 0 Linear Fit
Temperature Effects on SCD Output Shawn Rosofsky, UMD
Slope: 19.1 ADC Counts/ºC
![Page 7: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/7.jpg)
8
Selected Group 1 Fits
Temperature Effects on SCD Output Shawn Rosofsky, UMD
Slope: 19.1 ADC Counts/ºCIntercept: 5058.0 ADC Counts
Slope: 18.7 ADC Counts/ºCIntercept: 5173.0 ADC Counts
Slope: 18.4 ADC Counts/ºCIntercept: 5134.3 ADC Counts
Slope: 19.2 ADC Counts/ºCIntercept: 5018.5 ADC Counts
![Page 8: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/8.jpg)
9
Results of Group 1 Fits
• Slope– Mean: 18.6 ADC Counts /ºC– Standard Deviation: 0.3 ADC
Counts /ºC
• Intercept– Mean: 5089.6 ADC Counts – Standard Deviation: 60.5
ADC Counts
• Conclusion: – Groups of channels
characterize an SCD region’s response to temperature shifts
– Output of channels within a group may differ
Temperature Effects on SCD Output Shawn Rosofsky, UMD
![Page 9: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/9.jpg)
10
Selected Channels from Various Groups
Temperature Effects on SCD Output Shawn Rosofsky, UMD
Slope: 19.1 ADC Counts/ºCIntercept: 5058.0 ADC Counts
Slope: 21.0 ADC Counts/ºCIntercept: 4782.5 ADC Counts
Slope: 19.6 ADC Counts/ºCIntercept: 4697.7 ADC Counts
Slope: 14.6 ADC Counts/ºCIntercept: 4563.5 ADC Counts
![Page 10: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/10.jpg)
11
Histogram of Slopes
Temperature Effects on SCD Output Shawn Rosofsky, UMD
Mean: 17.1 ADC Counts/ºCStandard Deviation: 15.0 ADC Counts/ºC
![Page 11: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/11.jpg)
12
Outliers
• All but 9 channels had slopes between 0 and 35 ADC Counts/ºC
• Most of these outliers appeared within this range expect for a large spike in one of the data points – Spike typically appeared
in coldest measurement
Presentation Title Name, UMD
![Page 12: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/12.jpg)
13
Histogram of Slopes Excluding Outliers
Temperature Effects on SCD Output Shawn Rosofsky, UMD
Mean: 16.9 ADC Counts/ºCStandard Deviation: 2.6 ADC Counts/ºC
![Page 13: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/13.jpg)
14
Results
• Temperature has a significant effect on SCD output– 16.9 ADC Counts/ºC on average (excluding outliers)
• Effect appears linear in nature• Affects different regions of SCD differently• Groups of 16 consecutive channels display very
similar responses to temperature shifts
Temperature Effects on SCD Output Shawn Rosofsky, UMD
![Page 14: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/14.jpg)
15
Shortcomings
• Incomplete mapping of SCD channel location– Temperature used may not always be accurate
• Unable to analyze raw pedestal data output– Cannot independently verify means or determine
uncertainty
• Cause of outliers unknown
Temperature Effects on SCD Output Shawn Rosofsky, UMD
![Page 15: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/15.jpg)
16
Future Items
• Transient analysis of temperature change in SCD– Typical timescale for temperature shift
• Determine how much of a temperature shift significantly affects our data collection
• Decide how often to run pedestal measurements
Temperature Effects on SCD Output Shawn Rosofsky, UMD
![Page 16: Temperature Effects on SCD Output](https://reader034.vdocuments.pub/reader034/viewer/2022051720/58a42b111a28ab3e3d8b4d67/html5/thumbnails/16.jpg)
17
Cited Images
• 1) Jik Lee. Design, Fabrication and Performance of the Silicon Charge Detector for the ISS-CREAM. The 34th International Cosmic Ray Conference, 30 July- 6 August, 2015. The Hague, The Netherlands.
• 2) Rosemary Thorpe. ISS-CREAM Thermal and Fluid System Design and Analysis. TFAWS 2015 – August 3-7, 2015 – Silver Spring, MD.
Presentation Title Name, UMD