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PET Fundamentals: Electronics (1) Wu, Jinyuan Fermilab Apr. 2011.

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Presentation on theme: "PET Fundamentals: Electronics (1) Wu, Jinyuan Fermilab Apr. 2011."— Presentation transcript:

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2 PET Fundamentals: Electronics (1) Wu, Jinyuan Fermilab Apr. 2011

3 Fermi National Accelerator Laboratory Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 2

4 Colliding Experiments Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 3

5 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Questions PET? 511 keV? Back to Back? Speed of Light? ADC? TDC? FPGA? 4

6 PET Electronics Overview Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 5

7 Things to Measure Total Charge: Charge is measured to calculate the photon energy. Hit Time: To pair up two hits, timing resolution about 1 ns is needed. To improve imaging quality, time-of-flight (TOF) measurement good to ~50 ps is needed. Hit Position: The positions crystals being hit are end points of the chord line. Total Charge: Charge is measured to calculate the photon energy. Hit Time: To pair up two hits, timing resolution about 1 ns is needed. To improve imaging quality, time-of-flight (TOF) measurement good to ~50 ps is needed. Hit Position: The positions crystals being hit are end points of the chord line. Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 6 Array of Scintillator Crystals Photomultiplier Tubes (From Talk by Bill Moses, Search “OpenPET”)

8 What Is The Electronics Concept? Identify “Singles Events” Find Time Coincidences Between Singles Events w/  t “Coincident Event” = Pair of Singles Events Identify “Singles Events” Find Time Coincidences Between Singles Events w/  t “Coincident Event” = Pair of Singles Events Position (crystal of interaction) Time Stamp (arrival time) Energy Validation (=511 keV?) “Singles Event” Position (crystal of interaction) Time Stamp (arrival time) Energy Validation (=511 keV?) “Singles Event” tt Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 7 (From Talk by Bill Moses, Search “OpenPET”)

9 Energy Validation Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 8 ADC Shaper LP Filter PMT 

10 Identifying Time Coincidences Break Time Into Slices (100–250 ns / slice) Search for Singles Within  t max (4–12 ns) in Each Slice Break Time Into Slices (100–250 ns / slice) Search for Singles Within  t max (4–12 ns) in Each Slice Time Slice 1Slice 2Slice 3Slice 4Slice 5Slice 6 Single  t max Coincidence Single Coincidence Single Coincidence Single Coincidence Coincidence? Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 9 (From Talk by Bill Moses, Search “OpenPET”)

11 PET Detector Module Decode Crystals Using Anger Logic (Light Sharing) X-Ratio Y-Ratio Profile through Row 2 Array of Scintillator Crystals Photomultiplier Tubes Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 10 (From Talk by Bill Moses, Search “OpenPET”)

12 1234567 891011121314 15161718192021 22232425262728 29303132333435 363738304041 43444546474849 50515253545556 Position Identification 1234567 891011121314 15161718192021 22232425262728 29303132333435 3637 3839 4041 42 43444546474849 50515253545556 Y X E=A+B+C+D Y=(A+B)/E X=(B+D)/E C A D B Identify Crystal of Interaction Using Lookup Table Position Given by Crystal ID Identify Crystal of Interaction Using Lookup Table Position Given by Crystal ID Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 11 (From Talk by Bill Moses, Search “OpenPET”)

13 OpenPET Implementation (~2010) PMTs B Gain Adjust, Anti-Alias Gain Adjust, Anti-Alias Gain Adjust, Anti-Alias Gain Adjust, Anti-Alias Sum ADC V in V ref A C D Crystal Lookup (X & Y  ID) Energy Validation (E & ID  511?) Time Stamp (T & ID  T Stamp) Event Formatting Leading Edge TDC +5V A T FPGA & Memory ADC V in V ref +5V B ADC V in V ref +5V C ADC V in V ref +5V D Free-Running (~75 MHz) Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 12 (From Talk by Bill Moses)

14 Before ADC Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 13

15 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Cares Must Be Taken Outside FPGA (1) FPGA ADC Shaper LP Filter Band Limiting Spectrum of Original Signal LP filterADC Input Sampling In ADC Aliasing w/o LP Filtering Nyquist Frequency < (1/2) Sampling Frequency 14

16 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) The “Trend” vs. The Sampling Theorem There will be no hardware analog processing. Everything is done digitally in software. It sounds very stylish A shaper/low-pass filter is a minimum requirement. 15

17 Sampling Theorem! 采样定律! Sampling Theorem! Teorema De Amostragem! Abtast Theorem! Theorie d’Echautillonage! Samplings Teoremet! … Follow the sampling theorem strictly! Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov 16 PET Fundamentals: Electronics (1)

18 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 17 Cares Must Be Taken Outside FPGA (2) DAC FPGA ADC Shaper LP Filter n Dither Resolution finer than the ADC LSB can be achieved by adding noise at ADC input and digital filtering.

19 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Adding Noise for Finer Resolution Photo Credit: www.telegraph.co.uk, trinities.org Mechanical pressure gauges usually do not track small pressure changes well. The gauge readers may lightly tap the gauges to get more accurate reading. The idea of dithering at ADC input is similar. 18

20 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Why Band Limiting & Dithering are Ignored? Pre-amplifiers usually have a naturally limited bandwidth and an intrinsic noise larger than the LSB of the ADC. So a lot of time, band limiting and dithering can be “safely” ignored since they are satisfied automatically. High bandwidth, low noise devices now become easily accessible. A design can be too fast and too quiet.  Do not forget to review the band limiting and dithering requirements for each design. 19

21 Descriptions of Resolution Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 20

22 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Bin Width (If the distribution within the bin is uniform) 21 w v vnvn When the input signal value v to an ADC is within (v n -w/2, v n +w/2), the ADC outputs an integer n, representing that the input value is approximately v n. The bin width is a description of measurement errors, or measurement resolution. The bin width = (full range)/2^(number of bits): 8 bits: w = (full range)/256. 9 bits: w = (full range)/512. 10 bits: w = (full range)/1024.

23 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Standard Deviation Ref: http://en.wikipedia.org/ 22

24 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Full Width at Half Maximum (FWHM) (For Guassian distribution) 23

25 Commercial ADC Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 24

26 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) The Flash ADC Ref: http://www.scribd.com/doc/ 50291058/Flash-ADC-tutorial 8 bits: 256 Comparators 9 bits: 512 Comparators 10 bits: 1024 Comparators... 25

27 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) The Pipeline ADC Ref: http://www.maxim-ic.com/app-notes/index.mvp/id/810 8 bits = 4 bits + 4 bits 16 + 16 comparators 26

28 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Typical Circuit of ADC Applications Ref: http://www.analog.com/ 27

29 TDC Implemented in ASIC Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 28

30 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Traditional TDC Implemented in ASIC 29

31 Phase Detection and Delay Lock Loop  Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 30

32 TDC Implemented with FPGA Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 31

33 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Multi-Sampling TDC FPGA c0 c90 c180 c270 c0 Multiple Sampling Clock Domain Changing Trans. Detection & Encode Q0 Q1 Q2 Q3 QF QE QD c90 Coarse Time Counter DV T0 T1 TS Ultra low-cost: 48 channels in $18.27 EP2C5Q208C7. Sampling rate: 360 MHz x4 phases = 1.44 GHz. LSB = 0.69 ns. 4Ch Logic elements with non-critical timing are freely placed by the fitter of the compiler. This picture represent a placement in Cyclone FPGA 32

34 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) TDC Using FPGA Logic Chain Delay This scheme uses current FPGA technology Low cost chip family can be used. (e.g. EP2C8T144C6 $31.68) Fine TDC precision can be implemented in slow devices (e.g., 20 ps in a 400 MHz chip). IN CLK 33

35 Two Major Issues Due To Differential Non-Linearity 1.Widths of bins are different and varies with supply voltage and temperature. 2.Some bins are ultra-wide due to LAB boundary crossing Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov 34 PET Fundamentals: Electronics (1)

36 Auto Calibration Using Histogram Method Turn-key solution (bin in, ps out) Semi-continuous (auto update LUT every 16K events) Calibrates both DNL and temperature. DNL Histogram In (bin) LUT  Out (ps) 16K Events Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov 35 PET Fundamentals: Electronics (1)

37 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Calibration to the Center of Bins 36 w 0 /2+w 1 /2w 0 /2w 1 /2+w 2 /2w 2 /2+w 3 /2w 3 /2+w 4 /2

38 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Good, However Auto calibration solved some problems However, it won’t eliminate the ultra-wide bins  37

39 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Cell Delay-Based TDC + Wave Union Launcher Wave Union Launcher In CLK The wave union launcher creates multiple logic transitions after receiving a input logic step. The wave union launchers can be classified into two types: Finite Step Response (FSR) Infinite Step Response (ISR) This is similar as filter or other linear system classifications: Finite Impulse Response (FIR) Infinite Impulse Response (IIR) 38

40 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Wave Union Launcher A (FSR Type) In CLK 1: Unleash0: Hold Wave Union Launcher A 39

41 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Wave Union Launcher A: 2 Measurements/hit 1: Unleash 40

42 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Sub-dividing Ultra-wide Bins 1: Unleash 1 2 12 Device: EP2C8T144C6 Plain TDC:  Max. bin width: 160 ps.  Average bin width: 60 ps. Wave Union TDC A:  Max. bin width: 65 ps.  Average bin width: 30 ps. 41

43 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) FPGA TDC A possible choice of the TDC can be a delay line based architecture called the Wave Union TDC implemented in FPGA. Shown here is an ASIC-like implementation in a 144-pin device. 18 Channels (16 regular channels + 2 timing reference channels). This FPGA cost $28, $1.75/channel. (AD9222: $5.06/channel) LSB ~ 60 ps. RMS resolution < 25 ps. Power consumption 1.3W, or 81 mW/channel. (AD9222: 90 mW/channel) In CLK Wave Union Launcher A 42

44 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) More Measurements Two measurements are better than one. Let’s try 16 measurements? 43

45 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Wave Union Launcher B (ISR Type) Wave Union Launcher B In CLK 1: Oscillate0: Hold 44

46 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Wave Union Launcher B: 16 Measurements/hit 1 Hit 16 Measurements @ 400 MHz VCCINT =1.20V VCCINT =1.18V 45

47 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Delay Correction Delay Correction Process: Raw hits TN(m) in bins are first calibrated into TM(m) in picoseconds. Jumps are compensated for in FPGA so that TM(m) become T0(m) which have a same value for each hit. Take average of T0(m) to get better resolution. The raw data contains: U-Type Jumps: [48-63]  [16-31] V-Type Jumps: other small jumps. W-Type Jumps: [16-31]  [48-63] The processes are all done in FPGA. 46

48 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) The Test Module Two NIM inputs FPGA with 8ch TDC Data Output via Ethernet BNC Adapter to add delay @ 150ps step. 47

49 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Test Result NIM Inputs 0 12 RMS 10ps LeCroy 429A NIM Fan-out NIM/ LVDS NIM/ LVDS - 140ps Wave Union TDC B + + BNC adapters to add delays @ 140ps step. 48

50 Wave Union? Photograph: Qi Ji, 2010 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 49

51 Using FPGA as ADC Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 50

52 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) The Single Slope ADC Signal Source FPGA V REF Shaper Line Driver Shaper ADC Shaper FPGA TDC Line Driver Line Driver Line Driver Signal Source Shaper TDC Shaper TDC Shaper TDC Analog signal of each channel from the shaper is fed to a comparator and compared with a common ramping reference voltage V REF. Pulses, rather than analog signals are transmitted on the cable. The times of transitions representing input voltage values are digitized by TDC blocks inside FPGA. This approach sometimes is (mistakenly) refereed as “Wilkinson ADC”. T1T1 V1V1 T2T2 V2V2 ADC 51

53 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) The Wilkinson ADC Ref: Annu. Rev. Nucl. Part. Sci. 1995.45.’1-39 http://www.dnp.fmph.uniba.sk/~kollar/je_w/el3.htm 52

54 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1)  Consider sampling rate at 2 MHz, the whole ramping cycle is 500 ns.  Arrange 409.6 ns for upward ramping.  To achieve 12-bit ADC precision, the TDC LSB is (409.6 ns)/4096 = 100 ps.  TDC with 100 ps LSB can be comfortably implemented in FPGA today. TDC Resolution Requirement T1T1 V1V1 T2T2 V2V2 500 ns 53

55 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1)  Typical ADC devices creates noise that may interfere the analog circuits.  The time interval for resetting of the common reference voltage may be noisy but analog signal is not sampled during it.  There is no digital control activities during ramping up of the common reference voltage. Digital Noise During Digitization T1T1 V1V1 T2T2 V2V2 Noisy Clean ADCShaper 54

56 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Single Slope ADC Test: Waveform Digitization Raw Data Input Waveform, Overlap Trigger & Reference Voltage Calibrated FPGA TDC 50 1000pF 100 V REF Shown here is a demo of a 6-bit single slope TDC. Sampling rate in this test is 22 MHz. Both leading and trailing reference ramps are used in this example. Nonlinear reference ramping is OK. The measurement can be calibrated. 55

57 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Differential Inputs and Ramping Reference Voltage FPGA TDC RR C R1 V REF + 4xR2 V REF - V IN1 + V IN1 - V IN2 + V IN2 - 56

58 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) ADC Test Results 57

59 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) The Sigma-Delta ADC FPGA TDC R V CMP C V IN FPGA TDC RR C R1 V REF + 4xR2 V REF - V IN + V IN - 58

60 Recycling Integrator Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 59

61 Recycling Integrator for nA Measurement PET Fundamentals: Electronics (1) Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov 60

62 Cryogenic Ionization chamber 5k – 350K It is a helium-filled ionization chamber. It's current is proportional to the dose rate. ● The signal current is processed by a current to frequency converter to achieve a wide dynamic range and quick response dose rate excursions. ● All materials used are know to be radiation hard and suitable for operation at 5K. ● The electronics is self-contained and requires no computer to operate. PET Fundamentals: Electronics (1)Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov 61

63 The chamber housing is held at negative potential and negative charge is collected on the center electrode. The HV is -95 V and is kept well below the minimum breakdown voltage of 156V in Helium. Cryogenic Loss Monitor operation The electronics uses a recycling integrator as a current to frequency converter with a wide dynamic range. The charge per pulse is 1.63pC or 238µR at 1 atm (room temp) of He. The recycling integrator consist of a charge integrating amplifier with a 0.50 pF capacitance followed by a discriminator which senses when the capacitor is fully charged. PET Fundamentals: Electronics (1)Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov 62

64 Pulses at 150 nA and 300 nA Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 63

65 Input Current and Output Pulses Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Input Current 100 nA/div Output Pulses 64

66 Current Measurements Using TDC Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) I=Q/dt 65

67 The End Thanks

68 Gaussian Distribution Use MS Excel to plot the Gaussian distribution from mu -5 sigma to mu +5 sigma. For simplicity, assume sigma=1 and mu=10. Show that FWHM = 2.35482 sigma. If a detector has a energy measurement error sigma=10keV, after collecting 10000 photos of 511 keV, how many measurements will be within 511 keV +- 10 keV? +- 20 keV? +- 30 keV? (Optional) Use MS Excel to generate 10000 numbers with mean = 511 and sigma =10 and count numbers in [501, 521], [491, 531], [481, 541]. Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 67

69 Digitization Error Consider a bin in a digitizer covering a range of [a, a+w]. If the input v is within [a, a+w], the input is reported to have a nominal value a+w/2. Show that for uniform distribution, the standard deviation introduced is w/sqrt(12). Show that if the nominal value is not a+w/2, the standard deviation will be bigger. Use MS Excel to generate 10000 random numbers from 0 to 1 with uniform distribution, compare the standard deviation with the theoretical number. Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 68

70 Ultra-wide Bins Consider an ADC with 8 bins with widths: 3V, 1V, 1V, 1V, 1V, 1V, 1V, 1V, will the outputs of the ADC be different for inputs 4.7 and 5.7V? And for inputs 1.7 and 2.7V? If N input values are evenly distributed in 0 to 10V, how many measurement points will be found in each of these bins? For measurements in bins with width=1V and width=3V, what are the standard deviations of the measurements? What is the standard deviation of all measurements in entire 0 to 10V range. What is the equivalent bin width corresponding to the standard deviation calculated above? (Optional) Use MS Excel to generate 10000 random numbers from 0 to 10 with uniform distribution, compare the standard deviation with the calculated number. Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 69

71 Recycling Integrator Consider the recycling integrator above. If the charging current through R_C is 250 nA when the discriminator output is high, what are the output pulse width and interval between two pulses when the ion chamber current is 10 nA? 100 nA? 200 nA? Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 70

72 Pulses at 300 nA Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) 71

73 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Measurement Result for Wave Union TDC A Histogram Raw TDC + LUT 53 MHz Separate Crystal -- Wave Union Histogram Plain TDC:  delta t RMS width: 40 ps.  25 ps single hit. Wave Union TDC A:  delta t RMS width: 25 ps.  17 ps single hit. 72

74 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Digital Calibration Using Twice-Recording Method IN CLK Use longer delay line. Some signals may be registered twice at two consecutive clock edges. N 2 -N 1 =(1/f)/  t The two measurements can be used:  to calibrate the delay.  to reduce digitization errors. 1/f: Clock Period  t: Average Bin Width 73

75 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Digital Calibration Result Power supply voltage changes from 2.5 V to 1.8 V, (about the same as 100 o C to 0 o C). Delay speed changes by 30%. The difference of the two TDC numbers reflects delay speed. N2N2 N1N1 Corrected Time Warning: the calibration is based on average bin width, not bin-by-bin widths. 74

76 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Weighted Averages The weighted average is a special case of inner product. Multipliers are usually needed. y1y1 y2y2 y3y3 y4y4 y5y5 y6y6 y7y7 c1c1 c2c2 c3c3 c4c4 c5c5 c6c6 c7c7 d1d1 d2d2 d3d3 d4d4 d5d5 d6d6 d7d7 e1e1 e2e2 e3e3 e4e4 e5e5 e6e6 e7e7 X  X  X  75

77 Apr. 2011, Wu Jinyuan, Fermilab jywu168@fnal.gov PET Fundamentals: Electronics (1) Exponentially Weighted Average No multipliers are needed. The average is available at any time. It can be used to track pedestal of the input signals. s[n]=s[n-1]+(x[n]-s[n-1])/N N=2, 4, 8, 16, 32, … + s[n-1] x[n] - s[n] 1/2 K 76

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