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Multichannel integrated circuits for digital X-ray imaging with energy windowing K rzysztof Świentek Department of Nuclear Electronics FPNT, AGH Kraków K.Swientek @ftj.agh.edu.pl. Content. Introduction – multichannel ASICs Noise in MOS transistors
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Multichannel integrated circuits • for digital X-ray imaging • with energy windowing • Krzysztof Świentek • Department of Nuclear Electronics • FPNT, AGH Kraków • K.Swientek@ftj.agh.edu.pl
Content • Introduction – multichannel ASICs • Noise in MOS transistors • Crosstalk in mixed–mode integrated circuits • Random matching • RX64DTH– digital imaging using silicon detectors • Measurements results – chip tutorial • Summary
Introduction multichannel ASIC SET OF SENSORS ( silicon strip detector) Input signals - small amplitude (Qin = 1400 el) - stochastic character (amplitude, time) MULTICHANNEL INTEGRATED CIRCUITS (analogue & digital blocks) LIMITS: power & area LOW LEVEL OF NOISE 6.5 mm RX64DTH UNIFORMITY OF PARAMETERS CROSSTALK digital analogue
Noise in MOS transistors 1.Thermal noise of channel saturation linear 2. Flicker noise Simulations (HSPICE) Simulations (HSPICE) NLEV=3 NLEV=2, 3 BSIM3v3 (NIMOD=2) BSIM3v3 (NIMOD=2) Measurments – short channel effects (2-10x): ( velocity saturation, hot electrons) Measurments – short channel effects ( hot electrons, RST noise)
ANALOG BLOCKS DIGITAL BLOCKS GENERATION TRANSFER SILICON SUBSTRATE EFFECT CROSSTALK • Transfer: • common supply lines: parasitic inductance and resistance (Vind=LdI/dt) • common substrate: (substrateepi, VT=f(VSB), gmb) • Effects for analogue blocks: switching noise, oscillation etc. • Minimisation: • reducing the noise generation, • increasing the immunity of analogue part, • isolation techniques.
L L W W D RANDOM MATCHING MATCHING - identically design devices have different parameters P=P1-P2 (P/P) Number of cases P/P [%] For MOS transistors: VT0 , , CMOS 0.7m - (VT0) NMOS PMOS W/L=2m/0.7m 9.72 mV 19.43 mV W/L=1500m/1.5m 0.31 mV 0.63 mV
1. Matching bias condition differences:VT, , R a) b) 2. Reduce sensitivity - proper configuration(Kv Ci/Cj) 3. Monte-Carlo analysis using HSPICE (matching data for given technology) • 4. Symmetry in layout • bias, temperature, orientation, • common centroid geometry, unit cells, • surrounding, metal coverage
X-rays current pulses 100 m PC computer data, control Silicon strip detector Integrated circuit X-ray imaging using silicon strip detectors • Key system issues: • fully parallel signal processing for all channels. • only binary information (yes/no) is extracted from each strip. • data from each channel must be stored in the local buffer for the whole measurement period. Signal 10x smaller Stochastic High Energy Physics
RX64DTH -fully integrated 64-channel chip (CMOS 0.8 mm process) • RX64DTH consists of: • 64 front-end channels (preamplifier, shaper, two discriminators) • 128 pseudo-random counters (20-bit) • internal DACs: two 8-bit threshold setting and and three 5-bit for bias • internal calibration circuit (square wave 1mV-30 mV) • control logic • I/O circuit (interface to external bus) 37006500 m2
V 0 t Tp 1 V V 0 t t VT-HIGH VT-LOW Single analogue channel C3 C2 C5 Shaper Preamplifier Discriminators • Key design issues: • low noise (ENC200 el. rms, sensor ) • low power (3-5 mW/channel) • relatively fast shaping (Tp = 0.5 1s) • uniformity from channel to channel (gain, offset, noise) • immunity to switching noise
V t Tp V t Preamplifier & shaper SENSOR: Cdet Idet Rbias LIMITATIONS Minimum of noise (transistor dimensions, bias) 1. POWER 2. PEAKING TIME 3. SENSOR 4. PSRR, stability, matching. Simulation HSPICE Hand calculation Measurements (bias, temp., Tp) • DAC currents • IFED • IFEDSH • ICAS Other transistors M1: 500/1 M5: 2/120 M4: 100/10 Id = 500 A
V t Tp TP [s] ENC versus Peaking Time Noise types ENC – total noise ENCW – white voltage noise ENCf – 1/f voltage noise ENCi – white current noise Peaking time TP • Optimal the lowest noise • Fast Front-end increasing noise
V 1 1 VT-HIGH t Tp 0 0 VT-LOW Discriminator – offsets, crosstalk • AC coupling • differential stage(CMRR) • hysteresis • power supply lines, guard rings
Pseudo-random counters • 20 bit counters (large dynamic range of the image) • small layout area (only 8 transistor per bit) • 128 counters are grouped in the 8 blocks of 16 counters each (8 bit I/O bus to minimize the dead time)
Functionality & testability Calibration circuits: Qinj=CtVcal (500 el - 13000 el) Internal DACs: threshold setting, gain, peaking time 2 x threshold 8-bit 3 x bias 5-bit 1 x calibration 4-bit • I/O circuits: • LVDS standard (command, clock) • 8-bit data bus (tristate), • 3-bit address (up to 8 chips) 6 dacs
7 2 3 4 5 6 13 10 14 11 12 Digital guard ring Analog guard ring 8 9 Digital ground Analog ground Middle ring LAYOUT - floor plan, bias lines, pads • Isolation techniques • reduce inductance (separatebias line,pads), • floor plan, bias lines • keep “clean” substrate– LVDS • RC filters • guard rings, shielding • Floor plan • preamplifier & shaper • discriminators • counters & IOs • digital outputs • control logic • calibration • bias DACs
Window – threshold DAC’s • two independent DACs • common centroid matrix • mixed matrices • matching problem • need software correction Dac value [LSB] Difference between DAC HIGH and LOW Difference [mV] Difference [LSB] 7 LSB Dac value [LSB] Silicon: 3,67eV/el
Noise versus ICAS & Temp VTH = 255 VTL = scan VTH = scan VTL = 255 Source Pu238 + Cu Vdet = 130 V Vdd = 4.0 V Vddd = 4.0 V Peltier element for temp. Controled Temp.
Noise versus IFED • gain & offset const • window is 5 LSB • Peltier element } fast noise increasing pin-holes in detector leakeage current dead channels because out of operating point rescue increase IFED but ...
Simulation: TP & Gain as a function of IFEDSH shaper output Impulse height • TP = 0.7 – 1 s • Impulse fall ends 4 s 200 kHz TP
Gain, Offset & Noise versus IFEDSH • window is 5 LSB • Peltier element max (slow) peaking time TP min (fast)
Summary • Multichannel mix-mode ASIC : • —critical parameters connected together • — looking for a golden solution • Software corrections : • —DACs problem • — differences between the chips • Noise controling : • IFED – better detector lower noise • ICAS – the highier the beter (cooling ?) • IFEDSH – high gain gives low noise and speed • To do – measurements • — speed • — uniformity in 6-chip module