Presentation is loading. Please wait.

Presentation is loading. Please wait.

- TMS - Temperature Monitoring System in Topix Olave Jonhatan INFN section of Turin and Politecnico P PANDA Collaboration Meeting December 9 th 2014 -

Published byBrandon Chandler Modified over 7 years ago

Similar presentations

Presentation on theme: "- TMS - Temperature Monitoring System in Topix Olave Jonhatan INFN section of Turin and Politecnico P PANDA Collaboration Meeting December 9 th 2014 -"— Presentation transcript:

1 - TMS - Temperature Monitoring System in Topix Olave Jonhatan INFN section of Turin and Politecnico P PANDA Collaboration Meeting December 9 th 2014 - Forschungszentrum Jülich

2 Jülich, December 2014J. Olave - INFN -2 Outline  Motivation  Requirements  The circuit Architecture  Simulation results  Conclusion and Outlook Motivation Requirements Architecture Simulations Conclusion Outlook

3 Jülich, December 2014J. Olave - INFN -3 Motivation Requirements Architecture Simulations Conclusion Outlook  Test Board for Topix 4

4 Jülich, December 2014J. Olave - INFN -4 Motivation Requirements Architecture Simulations Conclusion Outlook  Test Board for Topix 4 Topix 4 Sensor LM95071

5 Jülich, December 2014J. Olave - INFN -5 Motivation  Test Board for Topix 4 Topix 4 Sensor LM95071 Layout of Topix 4 Motivation Requirements Architecture Simulations Conclusion Outlook

6 Jülich, December 2014J. Olave - INFN -6 Requirements Motivation Requirements Architecture Simulations Conclusion Outlook Voltage supply of 1.2 V CMOS 0.13 um technology Reduced silicon area Working range from 0° C to 100° C Low power consumption Clock frequency 160 MHz Good resolution (± 0.1°C) Calibration system Radiation hardness Digital output BASIC REQUIREMENTS ASIC REQUIREMENTS

7 Jülich, December 2014J. Olave - INFN -7 The Circuit Architecture Motivation Requirements Architecture Simulations Conclusion Outlook

8 Jülich, December 2014J. Olave - INFN -8  Basic idea to design a BandGap Reference (GBR) V1 = V1(T) ΔV1/ ΔT = α1 T + β1 T 2 + …. V2 = V2(T) ΔV2/ ΔT = α2 T + β2 T 2 + …. V REF (T) = k 1 V1(T) + k 2 V2 (T) It is possible to choose k1 and k2 in order to have ΔV REF / ΔT = 0 The T sensor Motivation Requirements Architecture Simulations Conclusion Outlook

9 Jülich, December 2014J. Olave - INFN -9 The T sensor  Basic idea BandGap Reference (GBR) V1 = V1(T) ΔV1/ ΔT = α1 T + β1 T 2 + …. V2 = V2(T) ΔV2/ ΔT = α2 T + β2 T 2 + …. Motivation Requirements Architecture Simulations Conclusion Outlook V REF (T) = k 1 V1(T) + k 2 V2 (T) It is possible to choose k1 and k2 in order to have ΔV REF / ΔT = 0

10 Jülich, December 2014J. Olave - INFN -10 NTC The T sensor Motivation Requirements Architecture Simulations Conclusion Outlook

11 Jülich, December 2014J. Olave - INFN -11 Bandgap Analog to Digital Converter Vt Vref Motivation Requirements Architecture Simulations Conclusion Outlook FIRST STEPS time Voltage [V] 1.2 Vt @ constant T Signal generator Digital Output

12 Jülich, December 2014J. Olave - INFN -12 Bandgap Analog to Digital Converter Vt Vref Digital Output Motivation Requirements Architecture Simulations Conclusion Outlook time Voltage [V] 1.2 Vt @ constant T Ramp Generator Signal generator Vramp information Comparator FIRST STEPS

13 Jülich, December 2014J. Olave - INFN -13 Bandgap Analog to Digital Converter Vt Vref Digital Output Motivation Requirements Architecture Simulations Conclusion Outlook time Voltage [V] 1.2 Vt @ constant T Ramp Generator Signal generator Vramp information MUXMUX Comparator FIRST STEPS

14 Jülich, December 2014J. Olave - INFN -14 Bandgap Analog to Digital Converter Vt Vref Digital Output Motivation Requirements Architecture Simulations Conclusion Outlook time Voltage [V] 1.2 Vt @ constant T Ramp Generator Signal generator Vramp information Counter Register A MUXMUX Register B Adder Devider Adder Offset Comparator FIRST STEPS

15 Jülich, December 2014J. Olave - INFN -15 Bandgap Analog to Digital Converter Vt Vref Digital Output Motivation Requirements Architecture Simulations Conclusion Outlook time Voltage [V] 1.2 Vt @ constant T Ramp Generator Signal generator Vramp information Counter Register A Control Unit MUXMUX Register B Adder Devider Adder Offset Comparator FIRST STEPS

16 Jülich, December 2014J. Olave - INFN -16 Bandgap Analog to Digital Converter Vt Vref Digital Output Motivation Requirements Architecture Simulations Conclusion Outlook time Voltage [V] 1.2 Vt @ constant T Ramp Generator Signal generator Vramp information Counter Register A Control Unit MUXMUX Register B Adder Devider Adder Offset Comparator FIRST STEPS

17 Jülich, December 2014J. Olave - INFN -17 Bandgap Analog to Digital Converter Vt Vref Digital Output Motivation Requirements Architecture Simulations Conclusion Outlook time Voltage [V] 1.2 Vt @ constant T Ramp Generator Signal generator Vramp information Counter Register A Control Unit MUXMUX Register B Adder Devider Adder Offset Comparator FIRST STEPS Vramp Analog Environment Digital Environment

18 Jülich, December 2014J. Olave - INFN -18 Motivation Requirements Architecture Simulations Conclusion Outlook FIRST STEPS Layout View (100 um x 100 um) Schematic View

19 Jülich, December 2014J. Olave - INFN -19 Motivation Requirements Architecture Simulations Conclusion Outlook Simulation results

20 Jülich, December 2014J. Olave - INFN -20  Variation of the supply voltage - ΔV ref / ΔV supply ≈ 1.4 mV/V - ΔV t / ΔV supply ≈ 1.4 mV/V  Variation with the temperature - ΔV ref / ΔT ≈ 10 -2 mV/°C - ΔV T / ΔT ≈ - 1.63 mV/°C ( IMPROVE ) BANDGAP AND SIGNAL GENERATOR Motivation Requirements Architecture Simulations Conclusion Outlook

21 Jülich, December 2014J. Olave - INFN -21  Variation of the supply voltage - ΔV ref / ΔV supply ≈ 1.4 mV/V - ΔV t / ΔV supply ≈ 1.4 mV/V  Variation with the temperature - ΔV ref / ΔT ≈ 10 -2 mV/°C - ΔV T / ΔT ≈ - 1.63 mV/°C ( IMPROVE ) BANDGAP AND SIGNAL GENERATOR SIGNAL AMPLIFICATION  Two stage op amp with single ended output  Good linearity of V T *  ΔV T / ΔT ≈ + 7.3 mV/°C Motivation Requirements Architecture Simulations Conclusion Outlook

22 Jülich, December 2014J. Olave - INFN -22 Motivation Requirements Architecture Simulations Conclusion Outlook RAMP GENERATOR

23 Jülich, December 2014J. Olave - INFN -23 Motivation Requirements Architecture Simulations Conclusion Outlook RAMP GENERATOR

24 Jülich, December 2014J. Olave - INFN -24  ΔV ramp /Δt ≈ 136 mV/us  Good control of the initial value (250 mV)  The time to discharge the capacitor is ≈ 30 ns Motivation Requirements Architecture Simulations Conclusion Outlook RAMP GENERATOR

25 Jülich, December 2014J. Olave - INFN -25  ΔV ramp /Δt ≈ 136 mV/us  Good control of the initial value (250 mV)  The time to discharge the capacitor is ≈ 30 ns COMPARATOR  Two stages folded cascode structure  2 CMOS inverters  offset = 5 mV  supply current = 3.5 uA Motivation Requirements Architecture Simulations Conclusion Outlook RAMP GENERATOR

26 Jülich, December 2014J. Olave - INFN -26 Motivation Requirements Architecture Simulations Conclusion Outlook DIGITAL PART Post PnR simulation

27 Jülich, December 2014J. Olave - INFN -27 Motivation Requirements Architecture Simulations Conclusion Outlook CONCLUSION  The system is able to extract the information as expected  Single analog and digital blocks tested with good results  The Digital layout is done and tested with good results

28 Jülich, December 2014J. Olave - INFN -28 Motivation Requirements Architecture Simulations Conclusion Outlook CONCLUSION OUTLOOK  Conclude the AMS simulations  Use SEU protections for the digital part  Reduce the silicon area used for the digital part  Start with the analog layout to perform more realistic simulations  The system is able to extract the information as expected  Single analog and digital blocks tested with good results  The Digital layout is done and tested with good results

29 Jülich, December 2014J. Olave - INFN -29 THANK YOU FOR YOUR ATTENTION

Download ppt "- TMS - Temperature Monitoring System in Topix Olave Jonhatan INFN section of Turin and Politecnico P PANDA Collaboration Meeting December 9 th 2014 -"

Similar presentations

SKIROC New generation readout chip for ECAL M. Bouchel, J. Fleury, C. de La Taille, G. Martin-Chassard, L. Raux, IN2P3/LAL Orsay J. Lecoq, G. Bohner S.

SKIROC New generation readout chip for ECAL M. Bouchel, J. Fleury, C. de La Taille, G. Martin-Chassard, L. Raux, IN2P3/LAL Orsay J. Lecoq, G. Bohner S.
HCC Analog Monitor HCC Design Review April 24, 2014 Mitch Newcomer Nandor Dressnandt Aditya Narayan Amogh Halergi Dawei Zhang* * Original design work 2010-2012.

HCC Analog Monitor HCC Design Review April 24, 2014 Mitch Newcomer Nandor Dressnandt Aditya Narayan Amogh Halergi Dawei Zhang* * Original design work
18/05/2015 Calice meeting Prague 2007 1 Status Report on ADC LPC ILC Group.

18/05/2015 Calice meeting Prague Status Report on ADC LPC ILC Group.
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.
Current-Mode Multi-Channel Integrating ADC Electrical Engineering and Computer Science Advisor: Dr. Benjamin J. Blalock Neena Nambiar 16 st April 2009.

Current-Mode Multi-Channel Integrating ADC Electrical Engineering and Computer Science Advisor: Dr. Benjamin J. Blalock Neena Nambiar 16 st April 2009.
Discussion #25 – ADCECEN 3011 Conversion Mosiah 5:2 2 And they all cried with one voice, saying: Yea, we believe all the words which though has spoken.

Discussion #25 – ADCECEN 3011 Conversion Mosiah 5:2 2 And they all cried with one voice, saying: Yea, we believe all the words which though has spoken.
An Analog Wavelet Transform CMOS Imager Chip

An Analog Wavelet Transform CMOS Imager Chip
August 12 2008SGSS front end, Summary August 2008 Edwin Spencer, SCIPP1 SGST Preview SCIPP, UC Santa Cruz Andrey Martchovsky Gregory Horn Edwin Spencer.

August SGSS front end, Summary August 2008 Edwin Spencer, SCIPP1 SGST Preview SCIPP, UC Santa Cruz Andrey Martchovsky Gregory Horn Edwin Spencer.
Major Modifications and System Modeling Use a Peltier cooler as an actuator instead of a power resistor. Relocate the ambient sensor further away from.

Major Modifications and System Modeling Use a Peltier cooler as an actuator instead of a power resistor. Relocate the ambient sensor further away from.
NA62 front end Layout in DM option Jan Kaplon/Pierre Jarron.

NA62 front end Layout in DM option Jan Kaplon/Pierre Jarron.
NA62 front end architecture and performance Jan Kaplon/Pierre Jarron.

NA62 front end architecture and performance Jan Kaplon/Pierre Jarron.
Objective of Lecture Discuss analog computing and the application of 1 st order operational amplifier circuits. Derive the equations that relate the output.

Objective of Lecture Discuss analog computing and the application of 1 st order operational amplifier circuits. Derive the equations that relate the output.
Operational Amplifiers

Operational Amplifiers
ALL-DIGITAL PLL (ADPLL)

ALL-DIGITAL PLL (ADPLL)
Operational Amplifiers David Lomax Azeem Meruani Gautam Jadhav.

Operational Amplifiers David Lomax Azeem Meruani Gautam Jadhav.
Calorimeter upgrade meeting – CERN – October 5 th 2010 Analog FE ASIC: first prototype Upgrade of the front end electronics of the LHCb calorimeter E.

Calorimeter upgrade meeting – CERN – October 5 th 2010 Analog FE ASIC: first prototype Upgrade of the front end electronics of the LHCb calorimeter E.
Flow sensor circuitry Eduard Stikvoort 00/1A The work was done in Philips Reaearch Eindhoven.

Flow sensor circuitry Eduard Stikvoort 00/1A The work was done in Philips Reaearch Eindhoven.
1 CMOS Temperature Sensor with Ring Oscillator for Mobile DRAM Self-refresh Control IEEE International Symposium on Circuits and Systems, 2008. Chan-Kyung.

1 CMOS Temperature Sensor with Ring Oscillator for Mobile DRAM Self-refresh Control IEEE International Symposium on Circuits and Systems, Chan-Kyung.
1 Process-Variation Tolerant Design Techniques for Multiphase Clock Generation Manohar Nagaraju +, Wei Wu*, Cameron Charles # + University of Washington,

1 Process-Variation Tolerant Design Techniques for Multiphase Clock Generation Manohar Nagaraju +, Wei Wu*, Cameron Charles # + University of Washington,

Similar presentations

Ads by Google