Your search keyword '"Emerson Vernon"' showing total 23 results

1. ColdADC: A 16-Channel Digitizer ASIC with 186 µV-rms noise and 10.5-bit ENOB at 77 K for the Deep Underground Neutrino Experiment

Author

S. Gao, Sandeep Miryala, D. A. Dwyer, H. S. Chen, D. Braga, S. Holm, Kam Biu Luk, T. Prakash, Grzegorz Deptuch, Jack Fried, Carl Grace, Chi Lin, M. Dabrowski, Y. Lu, Emerson Vernon, E. Lopriore, J. Zhang, D. C. Christian, J. Hoff, and A. Shenai

Subjects

Physics, Effective number of bits, CMOS, Application-specific integrated circuit, business.industry, Preamplifier, Detector, Hardware_INTEGRATEDCIRCUITS, Electrical engineering, Cryogenics, business, Noise (electronics), Communication channel

Abstract

A 16-channel, 12-bit, 2 MS/s Digitizer ASIC, called ColdADC, intended as the digitizer for the DUNE Single-Phase Far Detector, is presented. ColdADC has an input buffer per channel and two 16 MS/s Pipelined ADCs that each digitizes the output of 8 preamplifiers. The ASIC was developed using specialized design techniques for long-term reliability in cryogenic environments and a customized cryogenic standard cell library. ColdADC, with a die area of approximately 52.4 mm2 and fabricated in 65 nm CMOS technology, achieves 186 µV-rms noise performance and 10.5-bit ENOB at a temperature of 77 K, while dissipating 425 mW (26.6 mW per channel). The prototype has been successfully interoperated with the intended preamplifier at cryogenic temperatures.

Published

2020

2. A linear array of position-sensitive virtual Frisch-grid CdZnTe for low-energy gamma rays

Author

L. Ocampo Giraldo, Deidra Hodges, Giuseppe S. Camarda, Emerson Vernon, Jack Fried, G. De Geronimo, Aleksey E. Bolotnikov, Ralph B. James, and Anwar Hossain

Subjects

010302 applied physics, Physics, Nuclear and High Energy Physics, Interaction point, 010308 nuclear & particles physics, Preamplifier, business.industry, Detector, Gamma ray, 01 natural sciences, Cathode, law.invention, Anode, Optics, Application-specific integrated circuit, law, 0103 physical sciences, business, Instrumentation, Energy (signal processing)

Abstract

Large-area arrays of position-sensitive virtual Frisch-grid CdZnTe (CZT) detectors with enhanced energy resolution and high efficiency have been proposed for spectroscopy and imaging of gamma-ray sources. Here, we present the design and test results of a linear array of such detectors optimized for use in handheld instruments. There are several application areas for such detectors including uranium enrichment measurements, storage monitoring, dosimetry and other nuclear safeguards related tasks. The array configuration provides a large area with minimum number of readout channels, which potentially allows the developers to avoid using ASIC-based readout electronics by substituting it with hybrid preamplifiers followed by digitizers. The array prototype consists of 6 5 × 7 × 25 mm3 CZT detectors side-oriented with respect to the source to achieve the maximum area. Each detector is furnished with 5 mm-wide charge-sensing pads placed near the anode. As an option, the pads can be grouped together to reduce the number of readout channels. The same can be done with the cathodes. The pads signals are converted into X–Y coordinates and combined with the cathode signals (for the Z coordinates) to give 3D positional information of each interaction point. This information is used to correct the response non-uniformity caused by material inhomogeneity, which allows the developers to use standard grade (unselected) CZT crystals, while retaining high spectroscopic performance.

Published

2018

3. Characterization and QC practice of 16-channel ADC ASIC at cryogenic temperature for Liquid Argon TPC front-end readout electronics system in DUNE experiment

Author

S. Tang, Chi Lin, S. Holm, I. K. Furic, Grzegorz Deptuch, Sandeep Miryala, Emerson Vernon, D. C. Christian, J. Hoff, S. Gao, E. Lopriore, Jack Fried, Carl Grace, D. Braga, M. Dabrowski, H. S. Chen, T. Prakash, and J. Zhang

Subjects

Materials science, business.industry, Readout electronics, Characterization (materials science), Front and back ends, Application-specific integrated circuit, Neutrino detector, Ionization, Optoelectronics, business, Cryogenic temperature, Instrumentation, Mathematical Physics, Communication channel

Abstract

ColdADC is a low-noise 16-channel analog-to-digital converter ASIC designed for cold readout electronics of Liquid Argon Time Projection Chambers (LArTPCs) in the Deep Underground Neutrino Experiment (DUNE). ColdADC was specifically designed for operation at cryogenic temperatures (77 K–89 K). Cold electronics is considered to be an enabling technology for liquid argon detectors in neutrino experiments. The main function of the chip is to digitize signals from the 16-channel charge-sensitive amplifier designed at BNL (LArASIC) and send digitized signals to the data aggregator and serializer chip (COLDATA). ColdADC operates with a resolution of 12 bits and a sampling rate of 2 MS/s per channel. A complete characterization of prototype chips was conducted at cryogenic temperature, involving power consumption, noise and linearity performance. In the first DUNE Far-Detector module, 384000 data channels will be read out, corresponding to 24000 ColdADC chips. Therefore, systematic testing of ColdADC chips at cryogenic temperature is vital for the quality and reliability of DUNE Single-Phase modules. We have developed a Quality Control (QC) test stand that includes ColdADC evaluation and characterization at cryogenic temperature. The QC procedure was applied to a first batch of 33 chips, corresponding to 528 data channels. The obtained results meet all the required DUNE specifications for ColdADC. Moreover, the testing outcome allowed us to identify possibilities of performance optimization that are currently being addressed in the design of the next version of the chip. The Quality Control procedure is proved to be successful and will be a reference design for future large-batch production testing of final ColdADC ASICs.

Published

2021

4. Use of high-granularity CdZnTe pixelated detectors to correct response non-uniformities caused by defects in crystals

Author

Yonggang Cui, Emerson Vernon, Jack Fried, Utpal N. Roy, A. Emerick, John F. Eger, Cynthia Salwen, G. De Geronimo, Ge Yang, Giuseppe S. Camarda, Anwar Hossain, Ralph B. James, S.A. Soldner, and Aleksey E. Bolotnikov

Subjects

0301 basic medicine, Physics, 030103 biophysics, Nuclear and High Energy Physics, Pixel, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, business.industry, Instrumentation, Resolution (electron density), Detector, 01 natural sciences, Charge sharing, 03 medical and health sciences, Optics, Application-specific integrated circuit, 0103 physical sciences, Granularity, Spectral resolution, business

Abstract

Following our successful demonstration of the position-sensitive virtual Frisch-grid detectors, we investigated the feasibility of using high-granularity position sensing to correct response non-uniformities caused by the crystal defects in CdZnTe (CZT) pixelated detectors. The development of high-granularity detectors able to correct response non-uniformities on a scale comparable to the size of electron clouds opens the opportunity of using unselected off-the-shelf CZT material, whilst still assuring high spectral resolution for the majority of the detectors fabricated from an ingot. Here, we present the results from testing 3D position-sensitive 15×15×10 mm 3 pixelated detectors, fabricated with conventional pixel patterns with progressively smaller pixel sizes: 1.4, 0.8, and 0.5 mm. We employed the readout system based on the H3D front-end multi-channel ASIC developed by BNL's Instrumentation Division in collaboration with the University of Michigan. We use the sharing of electron clouds among several adjacent pixels to measure locations of interaction points with sub-pixel resolution. By using the detectors with small-pixel sizes and a high probability of the charge-sharing events, we were able to improve their spectral resolutions in comparison to the baseline levels, measured for the 1.4-mm pixel size detectors with small fractions of charge-sharing events. These results demonstrate that further enhancement of the performance of CZT pixelated detectors and reduction of costs are possible by using high spatial-resolution position information of interaction points to correct the small-scale response non-uniformities caused by crystal defects present in most devices.

Published

2016

5. Performance of 8×8×32 and 10×10×32 mm3 CdZnTe position-sensitive virtual Frisch-grid detectors for high-energy gamma ray cameras

Author

Ralph B. James, Jack Fried, J. Mackenzie, S. Taherion, L. Ocampo Girado, Eric Y. Chen, Gabriella Carini, F.J. Kumar, Aleksey E. Bolotnikov, G. De Geronimo, Emerson Vernon, and Kihyun Kim

Subjects

Physics, Nuclear and High Energy Physics, High energy, 010308 nuclear & particles physics, business.industry, Detector, Gamma ray, 02 engineering and technology, 021001 nanoscience & nanotechnology, Grid, 01 natural sciences, Optics, Application-specific integrated circuit, Nuclear safeguards, 0103 physical sciences, Waveform, 0210 nano-technology, business, Instrumentation, Dark current

Abstract

CdZnTe (CZT) crystals with thicknesses up to 20 mm and diameters up to 75 mm have become available from Redlen Technologies, Inc. for making large-volume gamma-ray detectors. The modified growth and optimized annealing conditions allowed Redlen to minimize the dark current and improve the uniformity of CZT crystals. Two detector designs, pixelated (H3D) and position-sensitive virtual Frisch-grid (VFG), have greatly benefitted from the availability of such big crystals. Encouraging results from testing of 40 × 40 × 15 mm 3 pixelated detectors were recently reported by the University of Michigan. Here, we evaluated the spectroscopic properties of 8 × 8 × 32 and 10 × 10 × 32 mm 3 crystals configured as position-sensitive VFG detectors. Both digitized waveforms and an analog ASIC were used to read and process the signals from the detectors and test their spectral- and spatial-resolution. The VFG design provides the flexibility to scale-up the dimensions of the detectors for the desired efficiency, while the position information allows for correcting the detectors’ response non-uniformity caused by crystal defects and devices geometry, thereby reducing the instrument cost and making them more feasible for emerging applications in gamma-ray astronomy, nonproliferation, portal screening and nuclear safeguards, where large detector arrays are often required.

Published

2020

6. A 4×4 array module of position-sensitive virtual Frisch-grid CdZnTe detectors for gamma-ray imaging spectrometers

Author

George Mahler, Kyoungwon Kim, Ge Yang, Anwar Hossain, G. De Geronimo, Giuseppe S. Camarda, Deidra Hodges, Emerson Vernon, Ralph B. James, Aleksey E. Bolotnikov, L. Ocampo Giraldo, and Jack Fried

Subjects

Physics, Nuclear and High Energy Physics, Spectrometer, 010308 nuclear & particles physics, business.industry, Detector, Gamma ray, 02 engineering and technology, 021001 nanoscience & nanotechnology, Grid, 01 natural sciences, Cathode, law.invention, Anode, Optics, Application-specific integrated circuit, law, Position (vector), 0103 physical sciences, 0210 nano-technology, business, Instrumentation

Abstract

Arrays of position-sensitive virtual Frisch-grid CdZnTe (CZT) detectors offer an economical approach to making high efficiency and high energy resolution gamma cameras for spectroscopy and imaging of radioactive sources. There are many application areas for such instruments including gamma-rays astronomy , medical and industrial imaging, nonproliferation and nuclear safeguards . Here we present the test results from a 4 × 4 array module coupled to the front-end ASIC. The array houses 16 detectors made of 6 × 6 × 20 mm3 CZT crystals. Each crystal is encapsulated inside an ultrathin polyester shell and furnished with four 5-mm-wide charge-sensing pads placed near the anode on each side of the detector. The pad’s signals are used to measure X–Y coordinates while the cathode signals give the interaction depths ( Z coordinates). Combined together the signals provide 3D position information of the interaction points which can be used to correct the detector response non-uniformity. This allows developers to use standard grade (unselected) CZT crystals while retaining high spectroscopic performance comparable with that of the H3D pixelated detectors. The array’s design provides flexibility to replace individual detectors and extend their sizes, potentially increasing upwards of 4 cm in height. We started development of position-sensitive VFG detectors several years ago and today this technology has reached a high-maturity level and is ready to use in practical applications.

Published

2020

7. 4x4 array of position-sensitive virtual Frisch-grid CdZnTe detectors for imaging and spectroscopy of gamma-ray sources (Conference Presentation)

Author

Giuseppe S. Camarda, Emerson Vernon, Ge Yang, Jack Fried, Ralph B. Jamese, Aleksey E. Bolotnikov, Gianluigi De Geronimo, Diedra R. Hodges, Luis Ocampo, and Anwar Hossain

Subjects

Materials science, business.industry, Detector, Gamma ray, Substrate (printing), Cathode, Anode, law.invention, Optics, Application-specific integrated circuit, Position (vector), law, Spectroscopy, business

Abstract

Arrays of position-sensitive virtual Frisch-grid CdZnTe (CZT) detectors offer an economical approach to make high-efficiency and high energy-resolution gamma cameras for spectroscopy and imaging of radioactive sources. There are many application areas for such instruments including gamma-ray astronomy, medical and industrial imaging, environmental cleanup, nonproliferation and nuclear safeguards. Here, we present the design and results from testing of a 4x4 array mounted on a fanout substrate coupled to a front-end ASIC. The current array houses up to 16 detectors with a cross section of 6x6 mm3 and thickness of 2 cm. However, the array’s design provides flexibility to extend its dimensions in conjunction with the opportunity to replace faulty individual detectors or higher-performing detectors with thicknesses potentially increased up to 4 cm. Each detector is encapsulated inside an ultra-thin polyester shell and furnished with 5 mm-wide charge-sensing pads placed near the anode. For each gamma-ray event the signals on the pads are converted into X-Y coordinates and combined with the cathode signals (for the Z coordinates) to give 3D positional information of all interaction points, which provides a high-spatial-resolution imaging capability for the array. Moreover, the positional information can be used to correct for the detectors’ response non-uniformities due to the presence of crystalline defects, which, in turn, allows the developers to use relatively economical standard-grade (unselected) CZT crystals, while retaining the high spectroscopic performance comparable to the large-volume pixelated detectors produced from more expensive monolithic CZT crystals.

Published

2018

8. Arrays of position sensitive virtual Frisch-grid detectors (Conference Presentation)

Author

Arnold Burger, Michael Fiederle, Luis A. Ocampo Giraldo, Aleksey E. Bolotnikov, Giuseppe S. Camarda, Emerson Vernon, Gianluigi De Geronimo, Larry Franks, Ge Yang, Rubi Gul, Jack Fried, Anwar Hossain, Stephen A. Payne, and Ralph B. James

Subjects

Physics::Instrumentation and Detectors, Computer science, business.industry, Detector, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Gamma ray, Grid, Application-specific integrated circuit, Feature (computer vision), Position (vector), Granularity, business, Energy (signal processing), Computer hardware

Abstract

We present new results from testing a small array of position-sensitive virtual Frisch-grid gamma-ray detectors. Such arrays provide high-detection efficiency, excellent energy and position resolution. They can be used in compact hand-held instruments or in large-area gamma ray imaging cameras. The high granularity position sensing enables these detectors to correct the response non-uniformity caused by crystal defects. This important feature allows one to achieve high detection performance while using standard-grade (unselected) CZT crystals, which is expected to reduce the overall cost of field deployable high-resolution CZT gamma ray detection instruments. Here, we report the results of testing several array prototypes with configurations designed for different applications.

Published

2017

9. Comparison of Analog and Digital Readout Electronics on the Processing of Charge-Sharing Events in Pixelated CdZnTe Detectors

Author

Giuseppe S. Camarda, Jack Fried, Michael Prokesch, Emerson Vernon, M. Marshall, J. Butcher, Aleksey E. Bolotnikov, Ge Yang, Anwar Hossain, Derek S. Bale, G. De Geronimo, S.A. Soldner, M. Petryk, Ralph B. James, Yonggang Cui, and Kyung Hyun Kim

Subjects

Physics, Nuclear and High Energy Physics, Pixel, Preamplifier, business.industry, Detector, Electrical engineering, Charge sharing, Nuclear Energy and Engineering, Application-specific integrated circuit, Nuclear electronics, Electronic engineering, Waveform, Electronics, Electrical and Electronic Engineering, business

Abstract

We present our results from testing 15×15×10 mm3 CdZnTe pixelated detectors using a readout system based on the H3D ASIC. Data obtained with an uncollimated 137Cs source helped reveal details of the operational principle of such devices, and how the pulse-processing electronics may influence their performance. The responses of individual pixels were compared by using two different pulse processing approaches based on the analog shaping (H3D ASIC) and fitting of the waveforms as read out from hybrid preamplifiers.

Published

2014

10. Design Considerations and Testing of Virtual Frisch-Grid CdZnTe Detector Arrays Using the H3D ASIC

Author

Emerson Vernon, Aleksey E. Bolotnikov, George Mahler, M. Marshall, O. Kopach, Jack Fried, Ge Yang, M. Petryk, Jamie Butcher, Kihyun Kim, Yonggang Cui, Gianluigi De Geronimo, Giuseppe S. Camarda, Ralph B. James, Anwar Hossain, P. M. Fochuk, and B. McCall

Subjects

Physics, Nuclear and High Energy Physics, Data acquisition, Nuclear Energy and Engineering, Application-specific integrated circuit, Virtual instrumentation, Nuclear electronics, Instrumentation, Detector, Electronic engineering, Diffraction topography, Integrated circuit design, Electrical and Electronic Engineering

Abstract

We discussed the design implementation and results from testing 2 × 2-, 3 × 3-, and 2 × 4-arrays of 6×6 ×15 mm3 CdZnTe virtual Frisch-grid detectors. In these measurements we employed a data acquisition system based on the H3D ASIC developed by BNL's Instrumentation Division in collaboration with the University of Michigan for 3D position-sensitive detectors. We used CZT crystals with a range of performance attributes to evaluate practical array configurations and detector-assembling procedures. The detector ratings were assigned based on the pulse-height spectra and correlated with data from X-ray diffraction topography measurements and X-ray response mapping obtained at BNL's National Synchrotron Light Source. The results helped us to better understand the performance limits of these detectors, and to identify future improvements in the array's design and requirements for the new readout ASIC.

Published

2013

11. VMM1—An ASIC for Micropattern Detectors

Author

Jack Fried, G. De Geronimo, Jessica Metcalfe, Shaorui Li, Emerson Vernon, N. Nambiar, and Venetios Polychronakos

Subjects

Physics, Nuclear and High Energy Physics, Muon, business.industry, Detector, Electrical engineering, MicroMegas detector, Capacitance, medicine.anatomical_structure, Upgrade, Nuclear Energy and Engineering, Application-specific integrated circuit, Atlas (anatomy), Electronic engineering, medicine, Electrical and Electronic Engineering, business, Communication channel

Abstract

We present VMM1, the first prototype of a family of front-end ASICs designed for the ATLAS muon upgrade. The ASIC will operate with MICROMEGAS and TGC detectors, providing charge and timing measurements along with other features including sub-hysteresis discrimination, address of the first event in real time, and digital output per channel for Time-over-Threshold measurements. The shaper, designed via the concept of Delayed Dissipative Feedback (DDF), supports analog dynamic ranges in excess of 10 \thinspace000. With a capacitance of 200 pF and a nominal peaking time of 25 ns, the ASIC offers resolution of charge and timing better than 1 fC and 1 ns, respectively, for input charges up to 2 pC. Designed in a commercial 130 nm technology it dissipates about 4.5 mW per channel.

Published

2013

12. Upgrading FLIR NanoRaider with the next Generation of CdZnTe Detectors. Goal - Integrate VFG detectors into FLIR R200. Advanced Virtual Grid ASIC (AVG-ASIC)

Author

Gianluigi De Geronimo, Aleksey E. Bolotnikov, Emerson Vernon, and Yonggang Cui

Subjects

Engineering, Application-specific integrated circuit, business.industry, Detector, Electrical engineering, Grid, business, Electronic circuit

Published

2016

13. Readout ASIC for 3D Position-Sensitive Detectors

Author

Cedric Herman, Zhong He, Paul O'Connor, Kim Ackley, Feng Zhang, G. De Geronimo, Angelo Dragone, Emerson Vernon, and Jack Fried

Subjects

Physics, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, business.industry, Amplifier, Detector, Electrical engineering, Signal, Cathode, Anode, law.invention, Nuclear Energy and Engineering, Application-specific integrated circuit, law, Nuclear electronics, Optoelectronics, Electrical and Electronic Engineering, business, Charge amplifier, Electronic circuit, Voltage

Abstract

We describe an application specific integrated circuit (ASIC) for 3D position-sensitive detectors. It was optimized for pixelated cadmium-zinc-telluride (CZT) sensors, and it measures, corresponding to an ionizing event, the energy and timing of signals from 121 anodes and one cathode. Each channel provides low-noise charge amplification, high-order shaping, along with peak- and timing-detection. The cathode's timing can be measured in three different ways: the first is based on multiple thresholds on the charge amplifier's voltage output; the second uses the threshold crossing of a fast-shaped signal; and the third measures the peak amplitude and timing from a bipolar shaper. With its power of 2 mW per channel the ASIC measures, on a CZT sensor connected and biased, charges up to 100 fC with an electronic resolution better than 200 e- rms. Our preliminary spectral measurements applying a simple cathode/anode ratio correction demonstrated a single-pixel resolution of 4.8 keV (0.72 %) at 662 keV, with the electronics and leakage current contributing in total with 2.1 keV.

Published

2008

14. Design and Characterization of the VMM1 ASIC for Micropattern Gas Detectors

Author

Venetios Polychronakos, Gianluigi De Geronimo, Shaorui Li, Emerson Vernon, N. Nambiar, Jack Fried, and Jessica Metcalfe

Subjects

Physics, Nuclear and High Energy Physics, CMOS, Application-specific integrated circuit, Detector, Electronic engineering, Gas electron multiplier, Linearity, MicroMegas detector, Integrated circuit design, Detectors and Experimental Techniques, Instrumentation, Noise (electronics)

Abstract

We present here the measurements of the first prototype VMM1 ASIC designed at Brookhaven National Laboratory in 130 nm CMOS and fabricated in spring 2012. The 64-channel ASIC features a novel design for use with several types of micropattern gas detectors. The data driven system measures peak amplitude and timing information in tracking mode and first channel hit address in trigger mode. Several programmable gain and integration times allows the flexibility to work with Micromegas, Thin Gap Chambers (TGCs), and Gas Electron Multiplier (GEM) detectors. The IC design architecture and features will be presented along with measurements characterizing the performance of the VMM1 such as noise, linearity of the response, time walk, and calibration range. The concept for use with Micromegas in ATLAS Upgrade will also be covered including characterization under test beam conditions.

Published

2013

15. CdZnTe position-sensitive drift detectors with thicknesses up to 5 cm

Author

Emerson Vernon, Ralph B. James, Aleksey E. Bolotnikov, V. Dedic, Giuseppe S. Camarda, Yonggang Cui, Paul J. Sellin, Uri El-hanany, Eric Y. Chen, R. Gallagher, S. Cheng, Ge Yang, G. De Geronimo, Anwar Hossain, Rubi Gul, J. Mackenzie, S. Taherion, L. Ocampo Giraldo, and Jack Fried

Subjects

010302 applied physics, Physics, Physics and Astronomy (miscellaneous), business.industry, Detector, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Electric charge, Optics, Application-specific integrated circuit, Position (vector), 0103 physical sciences, 0210 nano-technology, business, Gamma ray detection

Abstract

We investigated the feasibility of long-drift-time CdZnTe (CZT) gamma-ray detectors, fabricated from CZT material produced by Redlen Technologies. CZT crystals with cross-section areas of 5 5 mm2 and 6 6 mm2 and thicknesses of 20-, 30-, 40-, and 50-mm were configured as 3D position-sensitive drift detectors and were read out using a front-end ASIC. By correcting the electron charge losses caused by defects in the crystals, we demonstrated high performance for relatively thick detectors fabricated from unselected CZT material. VC 2016 AIP Publishing LLC.

Published

2016

16. Front-end ASIC for a liquid argon TPC

Author

D. Makowiecki, Shaorui Li, H. S. Chen, Alessio D'Andragora, Bo Yu, S. Rescia, V. Radeka, C. E. Thorn, Francesco Lanni, Emerson Vernon, N. Nambiar, and G. De Geronimo

Subjects

Physics, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, business.industry, Noise spectral density, Transistor, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, Integrated circuit, Noise (electronics), Capacitance, Multiplexing, law.invention, Analog front-end, Nuclear Energy and Engineering, Application-specific integrated circuit, CMOS, law, MOSFET, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, Field-effect transistor, Electrical and Electronic Engineering, business, Hardware_LOGICDESIGN

Abstract

We present a front-end application-specific integrated circuit (ASIC) for a wire based time-projection-chamber (TPC) operating in liquid Argon (LAr). The LAr TPC will be used for long baseline neutrino oscillation experiments. The ASIC must provide a low-noise readout of the signals induced on the TPC wires, digitization of those signals at 2 MSamples/s, compression, buffering and multiplexing. A resolution of better than 1000 rms electrons at 200 pF input capacitance for an input range of 300 fC is required, along with low power and operation in LAr (at 87 K). We include the characterization of a commercial technology for operation in the cryogenic environment and the first experimental results on the analog front end. The results demonstrate that complementary metal-oxide semiconductor transistors have lower noise and much improved dc characteristics at LAr temperature. Finally, we introduce the concept of “1/f equivalent” to model the low-frequency component of the noise spectral density, for use in the input metal-oxide semiconductor field-effect transistor optimization.

Published

2010

17. ASIC for high rate 3D position sensitive detectors

Author

Gianluigi De Geronimo, Emerson Vernon, Kim Ackley, Zhong He, Jack Fried, Feng Zhang, and Cedric Herman

Subjects

Physics, Nuclear and High Energy Physics, Dynamic range, business.industry, Detector, X-ray detector, Electrical engineering, Wide-bandgap semiconductor, Integrated circuit, Cathode, Anode, law.invention, Cadmium zinc telluride, chemistry.chemical_compound, Nuclear Energy and Engineering, Application-specific integrated circuit, chemistry, law, Nuclear electronics, Electronic engineering, Optoelectronics, Electrical and Electronic Engineering, business, Energy (signal processing), Communication channel

Abstract

We report on the development of an application specific integrated circuit (ASIC) for 3D position sensitive detectors (3D PSD). The ASIC is designed to operate with pixelated wide bandgap sensors like Cadmium-Zinc-Telluride (CZT), Mercuric Iodide (Hgl2) and Thallium Bromide (TIBr). It measures the amplitudes and timings associated with an ionizing event on 128 anodes, the anode grid, and the cathode. Each channel provides low-noise charge amplification, high-order shaping with peaking time adjustable from 250 ns to 12 μs, gain adjustable to 20 mV/fC or 120 mV/fC (for a dynamic range of 3.2 MeV and 530 keV in CZT), amplitude discrimination with 5-bit trimming, and positive and negative peak and timing detections. The readout can be full or sparse, based on a flag and single- or multi-cycle token passing. All channels, triggered channels only, or triggered with neighbors can be read out thus increasing the rate capability of the system to more than 10 kcps. The ASIC dissipates 330 mW which corresponds to about 2.5 mW per channel.

Published

2009

18. Front-end ASIC for pixilated wide bandgap detectors

Author

Jack Fried, Feng Zhang, Gianluigi De Geronimo, Zhong He, Cedric Herman, and Emerson Vernon

Subjects

Physics, Preamplifier, business.industry, Detector, Integrated circuit, Multiplexing, Particle detector, law.invention, CMOS, Application-specific integrated circuit, law, Optoelectronics, business, Position sensor

Abstract

A CMOS application specific integrated circuit (ASIC) was developed for 3D Position Sensitive Detectors (PSD). The preamplifiers were optimized for pixellated Cadmium-Zinc-Telluride (CZT) Mercuric-Iodide (HgI2) and Thallium Bromide (TlBr) sensors. The ASIC responds to an ionizing event in the sensor by measuring both amplitude and timing in the pertinent anode and cathode channels. Each channel is sensitive to events and transients of positive or negative polarity and performs low-noise charge amplification, high-order shaping, peak and timing detection along with analog storage and multiplexing. Three methodologies are implemented to perform timing measurement in the cathode channel. Multiple sparse modes are available for the readout of channel data. The ASIC integrates 130 channels in an area of 12 x 9 mm 2 and dissipates ~330 mW. With a CZT detector connected and biased, an electronic resolution of ~200 e- rms for charges up to 100 fC was measured. Spectral data from the University of Michigan revealed a cumulative single-pixel resolution of ~0.55 % FWHM at 662 KeV.

Published

2009

19. Front-end ASIC for high resolution X-ray spectrometers

Author

Brian D. Ramsey, J.A. Gaskin, G. Anelli, G. De Geronimo, Emerson Vernon, Pavel Rehak, Don Pinelli, Zheng Li, Jack Fried, and Wei Chen

Subjects

Physics, Low-voltage differential signaling, Nuclear and High Energy Physics, Materials science, Spectrometer, Silicon drift detector, business.industry, Electrical engineering, Integrated circuit, Capacitance, law.invention, Front and back ends, Nuclear Energy and Engineering, Application-specific integrated circuit, law, Interposer, Optoelectronics, Field-effect transistor, Electrical and Electronic Engineering, business

Abstract

We present an application specific integrated circuit (ASIC) for high-resolution X-ray spectrometers. The ASIC is designed to read out signals from a pixelated silicon drift detector (SDD). Each hexagonal pixel has an area of 15 mm2 and an anode capacitance of less than 100 fF. There is no integrated Field Effect transistor (FET) in the pixel, rather, the readout is done by wire-bonding the anodes to the inputs of the ASIC. The ASIC provides 14 channels of low-noise charge amplification, high-order shaping with baseline stabilization, and peak detection with analog memory. The readout is sparse and based on low voltage differential signaling. An interposer provides all the interconnections required to bias and operate the system. The channel dissipates 1.6 mW. The complete 14-pixel unit covers an area of 210 mm2, dissipates 12 mW cm-2, and can be tiled to cover an arbitrarily large detection area. We measured a preliminary resolution of 172 eV at -35 degC on the 6 keV peak of a 55Fe source.

Published

2007

20. An array of virtual Frisch-grid CdZnTe detectors and a front-end application-specific integrated circuit for large-area position-sensitive gamma-ray cameras

Author

Wonho Lee, Deidra Hodges, Aleksey E. Bolotnikov, Cynthia Salwen, George Mahler, Utpal N. Roy, Emerson Vernon, Ge Yang, Jack Fried, Anwar Hossain, Yonggang Cui, C. Cherches, M. Maritato, Ralph B. James, Giuseppe S. Camarda, G. De Geronimo, M. Petryk, and Kim Ackley

Subjects

Physics, Physics::Instrumentation and Detectors, business.industry, Detector, Gamma ray, Integrated circuit, Cathode, law.invention, Anode, Reduction (complexity), Front and back ends, Application-specific integrated circuit, law, Optoelectronics, business, Instrumentation

Abstract

We developed a robust and low-cost array of virtual Frisch-grid CdZnTe detectors coupled to a front-end readout application-specific integrated circuit (ASIC) for spectroscopy and imaging of gamma rays. The array operates as a self-reliant detector module. It is comprised of 36 close-packed 6 × 6 × 15 mm(3) detectors grouped into 3 × 3 sub-arrays of 2 × 2 detectors with the common cathodes. The front-end analog ASIC accommodates up to 36 anode and 9 cathode inputs. Several detector modules can be integrated into a single- or multi-layer unit operating as a Compton or a coded-aperture camera. We present the results from testing two fully assembled modules and readout electronics. The further enhancement of the arrays' performance and reduction of their cost are possible by using position-sensitive virtual Frisch-grid detectors, which allow for accurate corrections of the response of material non-uniformities caused by crystal defects.

Published

2015

21. The PDD ASIC: Highly Efficient Energy and Timing Extraction for High-Rate Applications

Author

G. De Geronimo, Paul O'Connor, A. Kandasamy, Emerson Vernon, Jack Fried, and Angelo Dragone

Subjects

High rate, Application-specific integrated circuit, Computer science, business.industry, Pulse (signal processing), Process (computing), Electrical engineering, Analog memory, business, Multiplexing, Computer hardware, Precision rectifier, Efficient energy use

Abstract

The peak detector derandomizer ASIC provides threshold discrimination, arbitration, peak and timing detection with analog memory, sparsification, and multiplexing for 32 input channels of analog pulse data. In this work the ASIC is characterized for high-rate operation. A new version of the ASIC, can process multiple events occurring at the same time and provides time-over-threshold measurement for pile up rejection.

Published

2006

22. ASIC with Multiple Energy Discrimination for High-Rate Photon Counting Applications

Author

Paul O'Connor, Emerson Vernon, Angelo Dragone, J. Grosholz, and G. De Geronimo

Subjects

Physics, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, business.industry, Photonic integrated circuit, Detector, Integrated circuit design, Capacitance, Pulse shaping, Photon counting, Computer Science::Hardware Architecture, Optics, Nuclear Energy and Engineering, Application-specific integrated circuit, Electrical and Electronic Engineering, business, Energy (signal processing)

Abstract

An ASIC for high rate photon counting measurements with multiple energy discrimination is presented. Optimized for pixelated CdZnTe sensors, the ASIC is composed of 64 channels with low-noise charge preamplification, high-order shaping (40ns minimum peaking time), and five window-discriminators with associated 16-bit counters. An efficient readout scheme allows simultaneous measurement and readout through a 60 MHz 16-bit output bus. The ASIC architecture and experimental results are reported, and the impact of the shaper order on the resolution, ballistic deficit, and pile-up is discussed.

Published

2006

23. Pile up rejection and multiple simultaneous events acquisition with the PDD ASIC

Author

Angelo Dragone, Francesco Corsi, Paul O'Connor, A. Kandasamy, Emerson Vernon, D. P. Siddons, G. De Geronimo, and Jack Fried

Subjects

Engineering, CMOS, Application-specific integrated circuit, business.industry, Pulse (signal processing), Electronic engineering, Process (computing), business, Pile, Precision rectifier, Peak detection

Abstract

The Peak Detector Derandomizer ASIC provides threshold discrimination, arbitration, peak and timing detection with analog memorization, sparsification, and multiplexation for 32 input channels of analog pulse data. In this work the ASIC a new version of the ASIC, that can process multiple events occurring at the same time and can provide time-over-threshold measurement for pile up rejection, is presented.