Electrical System Nov. 15, 2010 Monte Frandsen. Key Electronics Design Goals and Constraints Minimal...
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![Page 1: Electrical System Nov. 15, 2010 Monte Frandsen. Key Electronics Design Goals and Constraints Minimal change between ground and airborne observations Signals.](https://reader036.fdocuments.net/reader036/viewer/2022070323/56649da65503460f94a91a96/html5/thumbnails/1.jpg)
Electrical SystemNov. 15, 2010
Monte Frandsen
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Key Electronics Design Goals and Constraints
Minimal change between ground and airborne observations
Signals pass through a vacuum bulkhead
Signals (wires) transition between77K to ambient
Electronics, (pre-amps), are subject to changing environmental conditions
Packaging and connectors
Vacuum bulkhead
Size, placement, and number of wires
Thermal effects
Temperature gradients (wires)
Ambient-operating point shifts etc
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Primary Electronics Design Tasks
Cryo-Cooler Electrical IntegrationController
Power Supply
Temperature Sensors
LWIR Detector Interface
MWIR Interface
Connectors and Packaging
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Cryo-Cooler Integration
Cyro-cooler controller
Primarily a packaging task
Connectors and wiring
Power Supply Connector
Serial Port Connector
Cold head temperature sensor connections
Must be mounted within ??? from the cryo pump
—(waiting on info from the manufacturer)
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Cryo-Cooler Power Supply
Boosts voltage to 48V to provide power to the Sunpower GT controller
Requirements:
Can be remotely mounting away from optical bench.
Input Voltage 28VDC
Expected Input power requirements
~30 Amp peak current draw (<10 seconds)
~15 Amps Max continuous
Output Power
48VDC
15 Amps peak (< 10 Seconds)
300 Watts maximum continous load
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Cryo-Cooler Power Supply
Design
Based on the Vicor Maxi Power Module
Three modules paralleled to meet peak load and share the load current
Schematic based on manufacturer’s reference design
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Temperature Sensors
RTD
Cryo Cooler cold head. Supplied by manufacturer.
Two leads directly interface to the cryo-controller.
Two lead Cryo cooler heat sink temperature
Lakeshore DT-670 Si Diodes
Expected accuracy 0.1K around 77K
Can be individually calibrated for higher accuracy as required.
Trade off between operation range vs. sensitivity
Locations (tbd)
Jusdon 2N2222 Si Diode
Part of the LWIR detector assembly
Circuit expected the be the same as the DT-670 interface
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Temperature Sensors
LakeShore DT-670 Si Diode SensorsStandard temperature curve
4-wire measurement
Minimize lead errors due to temperature shifts.
May be able to use 2-lead system with reduced performance.
10µA Bias current
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Temperature Sensor Interface
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Low bandwidth-Low power
Component RequirementsPrecision amplifiers and Precision Reference
High stability
Very low drift /temperature coefficients Vos and Gain.
Resistors
Vishay precision bulk foil with TC < 1 ppm.
10.0µA
Vdd
Vss
+
–
R11
1V Ref
Rbias
Vdd
Vss
+
–
I-AmpDT-670
Rlead
Rlead Rlead
Rlead
Vout
Vdd
Vss
+
–
1Offset Trim
R1
R1
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LWIR Detector Signals
Requirements12 independent Channels
Expected Sensor Bias Currents
10mA - 40mA (originally this was 1mA to 50mA)
0.5V to 3V DC bias voltage across the detectors
100 Ω typical detector impedance
1mV dynamic range.
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LWIR Pre-Amp Circuit Design
DC Servo Integrator feedback topologyProven on previous MAS sensor
Integrator nulls DC-Errors.
Also nulls any other DC sources within the limitations of the op-amp.
Transfer function is a high pass filter with a very low cut-off frequency
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Σ
1. S
Vin VoutA
β
-
+
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LWIR Pre-Amp Circuit Design
AdvantagesSupports 2-wire interface
Nulls out ALL slow-time varying changes including
Vos
Lead –resistances shifts
Bias voltage shifts
Bias current shifts
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DisadvantagesNot an absolute metric (typically ratio-metric)
No common mode rejection
Practical limitations on the integrator will prevent the DC from being driven nulled to 0. (< 10mV typical)
Input signal must be chopped (AC)
In use and during calibration
Scan – “droop” or background fading pushes out the low-frequency cut-off.
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LWIR Pre-Amp Circuit Design
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Simplified Circuit1. Unity Gain2. Gain~10003. Integrator4. Difference Amplifier
Rb
R5
IBIAS
Vd
Vdd
Vss
+
–
Vb
R1
R2
Vdd
Vss
+
–
Ra
Rb
R4
Rt
Vdd
Vss
+
–12
3
4
C
Vout
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Key Amplifier Requirements
Amplifier 1. Unity GainUltra-Low Voltage Noise. Low 1/Fc-noise
Unity Gain Stable
Amplifier 2. High Gain (1000) InvertingUltra-Low Voltage Noise. Low 1/Fc-noise
GBW Product > 40MHz
Max-Freq ~40Khz
Amplifier 3. IntegratorUltra-Low Input Current
Precision (Low Vos)
Amplifier 4. Differential output preferred.
High capacitive loading
Short circuit protected
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Preliminary Noise Estimates
Noise Estimate summaryAssumptions
Temperature = 300K (~27°C)
Detector modeled at 82 Ohms
Op amp noise models typically change in the .1 to 10Hz range. Parameters are selected > 10Hz.
@Amplifier 1 LT1128 en~ 5nV/sqrt(Hz) (@ 10Hz)
@Amplifier 2 (LT1037) en~ 5nV/sqrt(Hz) (@ 10Hz)
After Stage 2 gain of 1000
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e1 1.761nV
Hz=
e2 e12
er22+ ein2
2+ elt10372+:= e2 8.506
nV
Hz=
eout 1000 e2:= eout 8.506μV
Hz=
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Preliminary Noise Estimates
Noise Estimate summary (continued)
With a 40kHz bandwidth, the expected mean noise output voltage~Vm ≈ eout*sqrt(Bandwidth)
Vm ≈ 1.7mV
LT-Spice Noise Simulation shows ~12mV/Hz1/2
--Still need to reconcile the differences
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Additional LWIR Error sources
Low frequency op amp noise
Op-Amp Power SupplyPSSR (at 40Khz) 60dB @1mV ripple 1mV error
Reference Voltage noise Primarily on the Bias voltage
Common Mode tbd
CrossTalk
EMI/EMC pickup from cryo-pumpShield cables near the pump.
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LWIR Output
Full Scale output ± 5V
Dynamic range from sensorDependent on the detectors
>± 1V
Differential output op-amp with reasonable drive capabilities to drive twisted pair line.
Nominal impedance 100Ω
Based on previous reference design
50Ω on each wire.
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MWIR Interface
Currently do not have sensor specifications
Cooled transimpedance pre-amp is part of the detector
Expected interfaceInstrumentation amplifier
Gain <100
Maximum Bandwidth 40Khz
4-wire interfacePower
Gnd
Signal
Signal-Gnd
Output Interface similar to LWIR
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Connectors and Wiring
Pre-Amp Interface (External)Total signals --33
12 LWIR
12 MWIR (11 slots unused)
9 Temperature
6 cold
1 Hot cryo pump temperature
1 preamp
Input Power +28V
~70 connections
D38999 Series III connectors
Insert: 21-35 (79 contacts #22). Plug PN: D38999/26WG35SN
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Connectors and Wiring
Pre-Amp to Vacuum ConnectorsConnections
Wire count for 4-wire interface system (separate wires for bias and signals)
Total signals --33
12 LWIR
12 MWIR (11 slots unused)
5 Temperature
2 LWIR
1 Cryo pump cold head
3 general
116 Connections (wire count)
Vacuum Bulkhead Connectors
3-50 pin DSUB Bulkhead connectors
PN#
Preamp Connectors
3-Micro-D style (MIL-DTL-83513 Style )
Lead-times. Lead-times may force migrations to standard DSUB connectors
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Connectors and Wiring
Cryo Pump Power Supply and Cryo Controller.D38999 Series III connectors
Inserts/Shells not yet finalized.
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