Switched capacitor DC-DC converter ASICs for the upgraded LHC trackers
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Switched capacitor DC-DC converter ASICs for the upgraded LHC trackers
M. Bochenek1,2, W. Dąbrowski2, F. Faccio1, S. Michelis1
1. CERN, Conseil Européen pour la Recherche Nucléaire 2. AGH, University of Science & Technology
Topical Workshop on Electronics for Particle Physics, TWEPP 2010
This research project has been supported by a Marie Curie Initial Training Network Fellowship of the European
Community’s & Seventh Framework Programme under contract number (PITN-GA-2008-211801-ACEOLE)
This project has received funding from the European Community's Seventh Framework Programme (FP7/2007-2013) under project SLHC-PP, Grant Agreement no 212114. ACEOLE
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Outline1. Powering schemes considered for upgraded ATLAS Inner
Tracker
2. Switched capacitor step-down converter proposed for the DC-DC powering scheme
A model of a simple step-down (2:1) converter and its practical implementation,
Designs of the non-overlapping clock generator and buffers.
3. Switched capacitor voltage doubler proposed for the serial powering scheme
A model of a simple voltage doubler and its practical implementation,
Designs of the non-overlapping clock generator, level shifters and buffers.
Due to the fact that the IBM 0.13 µm submission was delayed,
we have to wait for the results from the chips.22/09/2010
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1. Overview of the powering schemes considered for the upgraded ATLAS Inner Tracker
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Serial powering scheme
Good quality of analog and digital voltage: low output impedance of shunt regulator, possibility to use classical linear regulator → good filtering
efficiency.
No regulation on DC-DC, but the power consumption in the analog part is constant.
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DC-DC conversion technique
A low-dropout voltage regulator in the “analog bus” is required. No regulation on the digital power line
(required low impedance of DC-DC since the current consumption varies significantly in the digital part).
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2. Switched capacitor step-down converter
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A simple model of the step-down switched capacitor converter
Phase 2:• Switches S1 and S3 are opened,• Switches S2 and S4 are closed, • CX and CL are connected in parallel.
The simplest model for the 2:1 converter contains:• Four switches• Two capacitors 22/09/2010
Phase 1:• Switches S1 and S3 are closed,• Switches S2 and S4 are opened,• CX and CL are connected in
series.
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Types of losses in switching MOSFETsThe optimization process is based on minimizing the
contradictory types of losses in the switching MOSFETs
Conduction losses ( equal to: I2 • R ) – therefore the total resistance between the source and drain during the “ON” state, RDS(on) has to be as low as possible,
Switching losses ( equal to: ts• VDS • I • f ) – switching time, rise and fall time depend on the gate to drain capacitance CGD, internal resistance of the driver and the VTH,
Gate charge losses ( equal to: f • QG(TOT)• VDRIVE ) – are caused by charging up the gate capacitance and then dumping the charge to ground every cycle.
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Practical solution for the DC-DC step-down converter
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• VDD = 1.9 V• VOUT = 926 mV• IOUT = 60 mA• CX = 1000
nF• CL = 200 nF• f = 1
MHz
Power Efficienc
y= 97%(including all circuitry)
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Schematic diagram of the non-overlapping clock generator used in the step-down converter
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3.5 ns
3.5 ns
2 x NOR gate3 x inverter2 x current starved inverterC1 = C2 = 20 fF
allows for a clock signal separation of
3.5ns
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Buffer used in the step-down converter
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Two chains of scaled inverters with cross-coupled transistors
M1 and M2 allow to avoid the conduction current in the last inverter M3 / M4
This architecture of the buffer was used by S. Michelis in AMIS2
M1
M2
Top
Bottom
M3
M4
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Layout of the step-down converter
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200 µm
580 µm
M4
(NFE
T)
M3
(NFE
T)
M2
(NFE
T)
M1
(PFE
T)
M4 buffer M3 buffer Clock generator M2 buffer M1 buffer
M1 = 28.2 mm / 0.24 µm, M2 = M3 = 18.0 mm / 0.30 µm, M4 = 6.0 mm / 0.30 µm
Total area = 0.12 mm2
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Simulation cell for the transient analysis (including package components)
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Time response of the step-down converter (no wire bonds)
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17mV
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Time response of the step-down (wire bond inductance included)
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Vpp = 150 mV (for L=1nH)
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Power efficiency and output voltage vs. output current
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The converterwas optimizedfor IOUT=60 mA
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Results from the corner analysis
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2. Switched capacitor step-up converter
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A simple model of the step-up switched capacitor converter
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Phase 1:• Switches S1 and S3 are closed,• Switch S2 is opened,• Capacitor is charged to thesupply voltage VDD
Phase 2:• Switches S1 and S3 are opened,• Switch S2 is closed,• Bottom plate of the capacitor on VDD, while the capacitor maintains its charge VDDC (from the previous phase).
A simple model contains:• Three switches• One capacitor
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Practical solution for the voltage doubler
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1.5 V NFETs
2.5V PFETs
M1, M2 = 980 μm / 0.15 μmM3, M4 = 2000 μm / 0.24 μmM5, M6 = 10 μm / 0.24 μm
VDD = 0.9 VVOUT = 1.55 VIOUT = 32 mACPUMP = 470 nFCLOAD = 470 nFf = 500 kHz
Power Efficiency= 85%
(including all circuitry)
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Level shifter
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Because of poor driving capability of used big PMOS serial switchestwo level shifters are needed
The level shifter requires two voltage supply domains: input voltage supply (0.9 V) and output supply (1.6 V) - taken from the output of the charge pump
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Layout of the charge pump
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Buffers
VoltageDoubler
LevelShifters
ClockGenerator
200 µm
190 µm
Total area = 0.04 mm2
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Simulation cell for the transient analysis (including package components)
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Time response of the step-up converter (no wire bonds)
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4mV
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Time response of the step-up (wire bond inductance included)
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Vpp = 900 mV (for L=1nH)
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Power efficiency and output voltage vs. output current
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The converterwas optimizedfor IOUT = 30mA
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Results from the corner analysis
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Layout of the DCDC013
2x Step-downConverter
2x Step-upConverter
2 mm
2 mm
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Conclusions The results from the Spectre simulations are quite
promising:- η = 97% for the step-down converter,- η = 85% for the step-up converter.
The inductance of the bond wires causes fast voltage spikes – the padring was designed to reduce the influence of the bond wire inductance. Therefore, the use of the DC-DC converters mounted on the separate chip with C4 pads should be considered.
The chip was submitted at the end of August 2010.
The PCB board is now in production and will be ready before the arrival of the chips.
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Thank you!
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This research project has been supported by a Marie Curie Initial Training Network Fellowship of the European
Community’s & Seventh Framework Programme under contract number (PITN-GA-2008-211801-ACEOLE)
This project has received funding from the European Community's Seventh Framework Programme (FP7/2007-2013) under project SLHC-PP, Grant Agreement no 212114. ACEOLE
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3122/09/2010
3.5 ns
Backup