1 Monolithic Pixel Sensor in SOI Technology - First Test Results H. Niemiec, M. Koziel, T. Klatka, W. Kucewicz, S. Kuta, W. Machowski, M. Sapor University.

Slides:

Advertisements

Similar presentations

Compact IGBT Modelling for System Simulation Philip Mawby Angus Bryant.

Advertisements

PRAGUE November 2002 Monolithic Silicon Pixel Detectors in SOI Technology J. Marczewski, K. Domanski, P. Grabiec, M. Grodner,

Transistors (MOSFETs)

Physical structure of a n-channel device:

Metal Oxide Semiconductor Field Effect Transistors

Elettronica T A.A Digital Integrated Circuits © Prentice Hall 2003 Inverter CMOS INVERTER.

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,

Analog VLSI Design Nguyen Cao Qui.

EEL-6167 VLSI DESIGN SPRING 2004 TERM PROJECT Mirror Circuits: Design and Simulation Craig Chin Miguel Alonso Jr.

Digital Integrated Circuits© Prentice Hall 1995 Devices The MOS Transistor.

11/5/2004EE 42 fall 2004 lecture 281 Lecture #28 PMOS LAST TIME: NMOS Electrical Model – NMOS physical structure: W and L and d ox, TODAY: PMOS –Physical.

Snowmass 2005 SOI detector R&D Massimo Caccia, Antonio Bulgheroni Univ. dell’Insubria / INFN Milano (Italy) M. Jastrzab, M. Koziel, W. Kucewicz, H. Niemiec.

Fig Operation of the enhancement NMOS transistor as vDS is increased

Physical States for Bits. Black Box Representations.

Fig. 5.1 Physical structure of the enhancement-type NMOS transistor: (a) perspective view; (b) cross section. Typically L = 1 to 10 m, W = 2 to 500.

S. Reda EN160 SP’07 Design and Implementation of VLSI Systems (EN0160) Lecture 22: Material Review Prof. Sherief Reda Division of Engineering, Brown University.

Outline Noise Margins Transient Analysis Delay Estimation

DC and transient responses Lezione 3

Hybrid Active Pixel Sensors and SOI-Inspired Option M. Baranski, W. Kucewicz, S. Kuta, W. Machowski, H. Niemiec, M. Sapor University of Mining and Metallurgy,

CMOS VLSI Design4: DC and Transient ResponseSlide 1 EE466: VLSI Design Lecture 05: DC and transient response – CMOS Inverters.

Chap. 5 Field-effect transistors (FET) Importance for LSI/VLSI –Low fabrication cost –Small size –Low power consumption Applications –Microprocessors –Memories.

1 Mask Documentation of the EE/MatE129 Process Wafers D. W. Parent SJSU.

EE4800 CMOS Digital IC Design & Analysis

Digital Integrated Circuits A Design Perspective

© Digital Integrated Circuits 2nd Devices VLSI Devices  Intuitive understanding of device operation  Fundamental analytic models  Manual Models  Spice.

Digital Integrated Circuits© Prentice Hall 1995 Inverter THE INVERTERS.

Introduction Integrated circuits: many transistors on one chip.

ACES Workshop 3-4 March, 2009 W. Dabrowski Serial power circuitry in the ABC-Next and FE-I4 chips W. Dabrowski Faculty of Physics and Applied Computer.

ECE 331 – Digital System Design Transistor Technologies, and Realizing Logic Gates using CMOS Circuits (Lecture #23)

KIT – Universität des Landes Baden-Württemberg und nationales Forschungszentrum in der Helmholtz-Gemeinschaft KIT, Institut für Prozessdatenverarbeitung.

ECE 342 Electronic Circuits 2. MOS Transistors

SPiDeR  First beam test results of the FORTIS sensor FORTIS 4T MAPS Deep PWell Testbeam results CHERWELL Summary J.J. Velthuis.

TRAPPISTE Tracking Particles for Physics Instrumentation in SOI Technology Prof. Eduardo Cortina, Lawrence Soung Yee Institut de recherche en mathématique.

1 Delay Estimation Most digital designs have multiple data paths some of which are not critical. The critical path is defined as the path the offers the.

Module-3 (MOS designs,Stick Diagrams,Designrules)

Device Physics – Transistor Integrated Circuit

W.Kucewicz2004 Nuclear Science Symposium, Rome, October 16-22, Fully Depleted Monolithic Active Pixel Sensor in SOI Technology Presented by Wojciech.

The George Washington University School of Engineering and Applied Science Department of Electrical and Computer Engineering ECE122 – 30 Lab 5: Layout.

Chapter 07 Electronic Analysis of CMOS Logic Gates

The George Washington University School of Engineering and Applied Science Department of Electrical and Computer Engineering ECE122 – 30 Lab 3: Layout.

Process Monitor/TID Characterization Valencia M. Joyner.

Fabrication Technology(1)

LEPSI ir e s MIMOSA 13 Minimum Ionising particle Metal Oxyde Semi-conductor Active pixel sensor GSI Meeting, Darmstadt Sébastien HEINI 10/03/2005.

Foundry Characteristics

Norhayati Soin 05 KEEE 4426 WEEK 12/1 3/13/2005 KEEE 4426 WEEK 12 CMOS FABRICATION PROCESS.

MIT Lincoln Laboratory NU Status-1 JAB 11/20/2015 Advanced Photodiode Development 7 April, 2000 James A. Burns ll.mit.edu.

Digital Integrated Circuits© Prentice Hall 1995 Devices Jan M. Rabaey The Devices.

Ｅｘｅｒｃｉｓｅ TAIST ICTES Program VLSI Design Methodology Hiroaki Kunieda Tokyo Institute of Technology.

Notes on Transistor Sizing for equal pullup/pulldown We assume that electron mobility to hole mobility ratio is 2 in this class. This means that a minimum.

CMOS Fabrication nMOS pMOS.

NMOS FABRICATION 1. Processing is carried out on a thin wafer cut from a single crystal of silicon of high purity into which the required p-impurities.

Technology Overview or Challenges of Future High Energy Particle Detection Tomasz Hemperek

11. 9/15 2 Figure A 2 M+N -bit memory chip organized as an array of 2 M rows  2 N columns. Memory SRAM organization organized as an array of 2.

Thanushan Kugathasan, CERN Plans on ALPIDE development 02/12/2014, CERN.

1 Overview of Fabrication Processes of MOSFETs and Layout Design Rules.

Chapter 6 Copyright © 2004 The McGraw-Hill Companies, Inc. All rights reserved. High-Speed CMOS Logic Design.

W. Kucewicz a, A. A.Bulgheroni b, M. Caccia b, P. Grabiec c, J. Marczewski c, H.Niemiec a a AGH-Univ. of Science and Technology, Al. Mickiewicza 30,

CMOS VLSI Fabrication.

Test structures for the evaluation of TowerJazz 180 nm CMOS Imaging Sensor technology  ALICE ITS microelectronics team - CERN.

CHAPTER 6: MOSFET & RELATED DEVICES CHAPTER 6: MOSFET & RELATED DEVICES Part 2.

(Re)design of the C3PD analog pixel 1. The starting point for the design was the CCPDv3 front-end (this presentation tries to follow the way the design.

Circuit Delay Performance Estimation Most digital designs have multiple signal paths and the slowest one of these paths is called the critical path Timing.

Stick Diagrams Stick Diagrams electronics.

Low Mass, Radiation Hard Vertex Detectors R. Lipton, Fermilab Future experiments will require pixelated vertex detectors with radiation hardness superior.

Nonvolatile memories:

MOSFET The MOSFET (Metal Oxide Semiconductor Field Effect Transistor) transistor is a semiconductor device which is widely used for switching and amplifying.

SuperB SVT Silicon Sensor Requirements

VLSI Design MOSFET Scaling and CMOS Latch Up

Presentation transcript:

1 Monolithic Pixel Sensor in SOI Technology - First Test Results H. Niemiec, M. Koziel, T. Klatka, W. Kucewicz, S. Kuta, W. Machowski, M. Sapor University of Mining and Metallurgy, Krakow K. Domanski, P. Grabiec, M. Grodner, B. Jaroszewicz, A. Kociubinski, K. Kucharski, J. Marczewski, D. Tomaszewski Institute of Electron Technology, Warszawa M. Caccia University of Insubria, Como Presented by Halina Niemiec

2 At Prague  The concept of SOI active pixel sensor realized in wafer-bonded SOI substrate was presented  The technology development: technological challenges, test structures and experiments were described Detector  handle wafer High resistive 300  m thick Electronics  active layer Low resistive 1.5  m thick

3 Progress of the project Fabrication of SOI test structure (TS - SOI) was completed  First run – only standard CMOS devices produced  Second run – cavities for pixel junction created Prototype readout circuits in commercial technology were delivered First measurements of TS-SOI and prototype chips performed

4 SOI Test Structures TS-SOI chip  General technological test structures for parameters extraction, investigation of device mismatches, process control, reliability test  Examples of analogue and digital circuits for comparison simulation and measurements results  Specific test structures for SOI detector applications First two runs were performed on low resistive SOI substrates and no pixel junctions were produced.

5 TS-SOI – Results Reliability test structures  Chain of contact windows to the detectors  Metal1 serpentine over deep detector cavities The measurements indicated continuous electrical paths

6 TS-SOI – Results Examples of measured MOS characteristics PMOS W/L=20  m/10  m NMOS W/L=20  m/10  m

7 TS-SOI – Results Measurements of test structure consisting of current mirrors with exactly the same dimensions – neighbouring and distant devices investigated Technological mismatch studies Detailed measurements performed for left side of a wafer with 1.5  m thick active layer Left and right side of the wafer differs by implantation dose.

8 TS-SOI – Results NMOS transistors W/L=50  m/10  m W/L=15  m/3  m 15  m/3  m 50  m/10  m

9 TS-SOI – Results PMOS transistors W/L=50  m/10  m W/L=15  m/3  m 15  m/3  m 50  m/10  m

10 TS-SOI – Model extraction Extracted MOS models for first run of TS-SOI: level 1 and level 2. Extraction of level 3 model in progress. Characteristics simulated with level 2 model fit quite well measurements results

11 TS-SOI – Results DC characteristics were measured for digital cells (inverter, double load inverter, double load buffer, NAND and NOR gate) and simple amplifying stages (OS and OS-OG) Obtained characteristics will be used for device models validation

12 TS-SOI – Results Inverter: V T  2.5 V Max I VDD =160  A OS amplifier: Gain   A Gain   A

13 TS-SOI – Next steps Further works on technological files extraction and device mismatches studies Measurements of readout matrix (with input pads) in SOI technologies Production of test structures on high resistive substrates (already in progress) and measurements of complete sensors

14 Prototype readout circuits First prototype of the readout circuit was designed and fabricated in 0.8 AMS technology Architecture of a readout circuit is being tested before the technological works are finished Technology properties and the readout circuit operation are investigated separately Compatibility was obtained by special design techniques: Re-scaling transistor dimensions to obtain the same gate capacitances and width to length (W/L) ratios like in IET-SOI technology Using most crucial IET-SOI design rules for the layout – the same drain diffusion areas, the same metal lines widths

15 Architecture of prototype chip The prototype readout circuit consists of 2 matrices with 256 (16x16) channels. Detecting diode is replaced by injection capacitance.

16 Prototype chip Implemented readout technique combines rolling-shutter with CDS Detector dead time is limited to the reset time of integrating element Integration time of every channel is adjustable and well defined

17 Prototype chip - Results Transfer characteristic Output range:  1.75 V Nonlinearity:  5%

18 Prototype chip – Next steps Further validation of prototype readout circuits  Estimation of maximum readout speed  Investigation of possible parasitic effects, like cross- talk, gradient across the circuit, etc. Basing on the results of prototype chips measurements the readout circuit in SOI technology will be designed