Presentation is loading. Please wait.

Presentation is loading. Please wait.

SOI Detector (1) Mateusz Baszczyk, Piotr Dorosz, Sebastian Głąb, Wojciech Kucewicz, Łukasz Mik, Maria Sapor (2) Imran Ahmed, Tomasz Fiutowski, Marek Idzik,

Published byJuliet Davis Modified over 9 years ago

Similar presentations

Presentation on theme: "SOI Detector (1) Mateusz Baszczyk, Piotr Dorosz, Sebastian Głąb, Wojciech Kucewicz, Łukasz Mik, Maria Sapor (2) Imran Ahmed, Tomasz Fiutowski, Marek Idzik,"— Presentation transcript:

1 SOI Detector (1) Mateusz Baszczyk, Piotr Dorosz, Sebastian Głąb, Wojciech Kucewicz, Łukasz Mik, Maria Sapor (2) Imran Ahmed, Tomasz Fiutowski, Marek Idzik, Jakub Moroń (3) Piotr Kapusta (1) Department of Electronics, (2) Department of Particle Interaction and Detection Techniques AGH – University of Science and Technology, Al. Mickiewicza 30, 30-059 Krakow, Poland (3) Institute of Nuclear Physics Polish Academy of Science Radzikowskiego 152, 31-342 Krakow, Poland

2 Agenda Chip topology Pixel circuit; Band Gap voltage source; Analogue to digital converter; Digital library; Summary; Future work. 2

3 Assumptions Detector has to work but it’s parameters are not so important. Pixels with CDS and rolling shutter readout scheme. Possibility to measure wafer temperature. Functional 10 bit ADC with parallel data output (LVDS). We will take part in July submission. 3

4 Chip layout 4 Detector has 32 pix x 32 pix; Two slightly different layouts of pixel; Two Band Gaps; Two 10 bit SAR ADCs; Differential voltage signal.

5 Chip 5

6 Pixel 6 Designed by Piotr Kapusta

7 Pixel layout (30 um x 30 um) 7 Designed by Piotr Kapusta

8 Negative temperature coefficient 8 Forward voltage of p-n junction V BE has negative TC. With V BE = 750 mV, T = 300 K: Temperature exponent of mobility: Thermal voltage: Bandgap energy of silicon:

9 Positive temperature coefficient 9 It was recognized in 1964 that if two bipolar transistors operate at unequal current densities, then the difference between their base-emitter voltages is directly proportional to the absolute temperature.

10 Band Gap 10

11 Band Gap (280 um x 425 um) 11

12 Band Gap („cold” diode model) 12

13 Band Gap („hot” diode model) 13

14 ADC (theory) 14 +-+- +-+- DACDAC SARSAR Shift register B n-1 B n-2 B 0 V DA V in SAR register: 100 110 111 110 111 110 101 100 011 010 001 000 111 110 101 100 011 010 001 000 V IN

15 ADC 15 Designed by Marek Idzik and Tomasz Fiutowski

16 ADC (100 um x 400 um) 16 Designed by Marek Idzik and Tomasz Fiutowski

17 Sampling circuit with bootstrap 17 Designed by Marek Idzik and Tomasz Fiutowski

18 Sampling circuit with bootstrap 18 M. Dessouky, A. Kaiser, Input switch configuration suitable for rail-to-rail operation of switched opamp circuits; Elect. Lett., vol. 35, no. 1, pp. 8-10, Jan. 1999.

19 Sampling circuit with bootstrap 19 M. Dessouky, A. Kaiser, Input switch configuration suitable for rail-to-rail operation of switched opamp circuits; Elect. Lett., vol. 35, no. 1, pp. 8-10, Jan. 1999.

20 Sampling circuit with bootstrap 20 Designed by Marek Idzik and Tomasz Fiutowski

21 9 bit DAC (segmented) 21 Designed by Marek Idzik and Tomasz Fiutowski

22 Dynamic comparator 22 Designed by Marek Idzik and Tomasz Fiutowski

23 Dynamic comparator 23 Designed by Marek Idzik and Tomasz Fiutowski

24 Delay based on thyristor 24 Designed by Marek Idzik and Tomasz Fiutowski

25 Delay based on thyristor 25 Designed by Marek Idzik and Tomasz Fiutowski

26 Digital library 26 94 Cells (81 completed, 13 missing layout). Adders, AND, AndOrInvert, Buffer, Buffer with Enable, Tristate Buffer, D Flip-Flops, D Latches, INV, JK Flip-Flops, Multiplexers, NAND, NOR, OR, T Flip-Flops, XNOR, XOR.

27 DigitalLib Two libraries: Gates and DigitalLib. Gates contains parameterized symbols and is used to draw schematics of DigitalLib. HDF_DYNAMIC and DF_DYNAMIC were drawn by Tomasz Fiutowski. These cells have different layout constraints. MESH is a template for layout drawing. These cells do not have layout: D Flip-Flops with Enable, all JK Flip-Flops, most of T Flip-Flops. All cells have passed simulation, DRC and LVS test. But I do not give any guarantee for correct operation of digital circuit – you must test it by yourself!!! 27

28 Conclusions We have designed first SOI detector in Lapis technology. It is starting point for further improvements; Simulation results have shown correct operation of ADC and Band gap voltage source; Digital library containing low height cells was made; (not tested yet) 28

29 Future work IC will be measured immediately after shipment. It is possible to use SeaBoard as acquisition system. We plan to use column ADC to increase readout speed. Due to large amount of digital data we will design serializer and phased locked loop. We would like to take part in January MPW run. 29

30 Thank you for your attention 30

Download ppt "SOI Detector (1) Mateusz Baszczyk, Piotr Dorosz, Sebastian Głąb, Wojciech Kucewicz, Łukasz Mik, Maria Sapor (2) Imran Ahmed, Tomasz Fiutowski, Marek Idzik,"

Similar presentations

Power Semiconductor Systems I

Power Semiconductor Systems I
TTL (Transistor Transistor Logic).  Transistor Transistor logic or just TTL, logic gates are built around only transistors.  TTL was developed in 1965.

TTL (Transistor Transistor Logic).  Transistor Transistor logic or just TTL, logic gates are built around only transistors.  TTL was developed in 1965.
Introduction to Digital Systems By Dr. John Abraham UT-Panam.

Introduction to Digital Systems By Dr. John Abraham UT-Panam.
1 Research & Development on SOI Pixel Detector H. Niemiec, T. Klatka, M. Koziel, W. Kucewicz, S. Kuta, W. Machowski, M. Sapor, M. Szelezniak AGH – University.

1 Research & Development on SOI Pixel Detector H. Niemiec, T. Klatka, M. Koziel, W. Kucewicz, S. Kuta, W. Machowski, M. Sapor, M. Szelezniak AGH – University.
1 Full-size Monolithic Active Pixel Sensors in SOI Technology - design considerations, simulations and measurements results on behalf of: M. Jastrzab,

1 Full-size Monolithic Active Pixel Sensors in SOI Technology - design considerations, simulations and measurements results on behalf of: M. Jastrzab,
Analog Peak Detector and Derandomizer G. De Geronimo, A. Kandasamy, P. O’Connor Brookhaven National Laboratory IEEE Nuclear Sciences Symposium, San Diego.

Analog Peak Detector and Derandomizer G. De Geronimo, A. Kandasamy, P. O’Connor Brookhaven National Laboratory IEEE Nuclear Sciences Symposium, San Diego.
A Low-Power 9-bit Pipelined CMOS ADC for the front-end electronics of the Silicon Tracking System Yuri Bocharov, Vladimir Butuzov, Dmitry Osipov, Andrey.

A Low-Power 9-bit Pipelined CMOS ADC for the front-end electronics of the Silicon Tracking System Yuri Bocharov, Vladimir Butuzov, Dmitry Osipov, Andrey.
Design and Implementation a 8 bits Pipeline Analog to Digital Converter in The Technology 0.6 μm CMOS Process Eri Prasetyo.

Design and Implementation a 8 bits Pipeline Analog to Digital Converter in The Technology 0.6 μm CMOS Process Eri Prasetyo.
2-1 ECE 424 Design of Microprocessor-Based Systems Haibo Wang ECE Department Southern Illinois University Carbondale, IL 62901 Fundamentals of Digital.

2-1 ECE 424 Design of Microprocessor-Based Systems Haibo Wang ECE Department Southern Illinois University Carbondale, IL Fundamentals of Digital.
Snowmass 2005 SOI detector R&D Massimo Caccia, Antonio Bulgheroni Univ. dell’Insubria / INFN Milano (Italy) M. Jastrzab, M. Koziel, W. Kucewicz, H. Niemiec.

Snowmass 2005 SOI detector R&D Massimo Caccia, Antonio Bulgheroni Univ. dell’Insubria / INFN Milano (Italy) M. Jastrzab, M. Koziel, W. Kucewicz, H. Niemiec.
1 32-bit parallel load register with clock gating ECE Department, 200 Broun Hall, Auburn University, Auburn, AL 36849, USA Lan Luo ELEC.

1 32-bit parallel load register with clock gating ECE Department, 200 Broun Hall, Auburn University, Auburn, AL 36849, USA Lan Luo ELEC.
Informationsteknologi Friday, October 19, 2007Computer Architecture I - Class 81 Today’s class Digital Logic.

Informationsteknologi Friday, October 19, 2007Computer Architecture I - Class 81 Today’s class Digital Logic.
Unit 12 Registers and Counters Ku-Yaw Chang Assistant Professor, Department of Computer Science and Information Engineering Da-Yeh.

Unit 12 Registers and Counters Ku-Yaw Chang Assistant Professor, Department of Computer Science and Information Engineering Da-Yeh.
Lab 04 :Serial Data Control Systems : Slide 2 Slide 3 Slide 4 NOR Gate: NAND Gate: NOR / NAND Alternate Symbols: Slide 5 XOR and XNOR Gate: Serial Data.

Lab 04 :Serial Data Control Systems : Slide 2 Slide 3 Slide 4 NOR Gate: NAND Gate: NOR / NAND Alternate Symbols: Slide 5 XOR and XNOR Gate: Serial Data.
ETE Digital Electronics

ETE Digital Electronics
ECE 301 – Digital Electronics Flip-Flops and Registers (Lecture #15)

ECE 301 – Digital Electronics Flip-Flops and Registers (Lecture #15)
REFERENCE CIRCUITS A Reference Circuit is an independent voltage or current source which has a high degree of precision and stability. Requirements of.

REFERENCE CIRCUITS A Reference Circuit is an independent voltage or current source which has a high degree of precision and stability. Requirements of.
REFERENCE CIRCUITS A reference circuit is an independent voltage or current source which has a high degree of precision and stability. Output voltage/current.

REFERENCE CIRCUITS A reference circuit is an independent voltage or current source which has a high degree of precision and stability. Output voltage/current.
Computer Electronics Course Overview  Includes  Unit Content summary  Pages to review from Textbook  Sample questions  Vocabulary reminders.

Computer Electronics Course Overview  Includes  Unit Content summary  Pages to review from Textbook  Sample questions  Vocabulary reminders.
Engineering Lecture 3 Digital Electronics by Jaroslaw Karcz.

Engineering Lecture 3 Digital Electronics by Jaroslaw Karcz.

Similar presentations

Ads by Google