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GIFTS Blackbody Subsystem Critical Design Review Blackbody Controller

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Title: GIFTS Blackbody Subsystem Critical Design Review Blackbody Controller


1
GIFTSBlackbody SubsystemCritical Design Review
Blackbody Controller
  • 9 March 2004
  • Scott Ellington
  • sellington_at_ssec.wisc.edu
  • 608 263-6771

2
Blackbody Controller
  • Performance Requirements and Design Overview
  • Changes since PDR
  • Controller Operation
  • Electronics Error Budget
  • Power Budget
  • Supporting Analysis
  • Part Selection
  • Engineering Model Test Results
  • Controller Verification Plan
  • Calibration Overview

3
Subsystem Block Diagram
4
Key Electronics Requirements
  • Blackbody Temperature Measurement
  • Hot Blackbody Range 0 to 40C
  • Ambient Blackbody Range -40 to 0C
  • Long-term accuracy 0.03C (Electronics only)
  • Measurement Update Rate 2.7 Hz
  • Blackbody Temperature Control
  • Constant Temperature and Constant Power Modes
  • HBB Control Temperature Range 0 to 40C
  • ABB Control Temperature Range -40 to 0C
  • Set Point Resolution 0.2C
  • Set Point Drift 0.005C, for a Controller board
    temperature change of 1C
  • Electronics Power 1.2 W, maximum

5
Changes Since PDR
  • Control of both blackbodies
  • Maximum total power increases from 3.0 to 5.2 W
  • Redundant heater drivers deleted, dual heaters
    retained
  • Add low power Reset mode
  • Default operation for both blackbodies is
    constant temperature
  • Add autoranging of temperature measurement ranges
  • Change 15V supplies to 12V
  • Add primary overtemperature protection
  • Increase measurement update rate from 2.0 to 2.7
    Hz
  • Command and data interface modified as necessary
  • Blackbody thermal environment is colder
  • Increase electronics power from 1.0 to 1.2 W
  • Change controller operating temperature range to
    -55 to 50C. (Accuracy guaranteed -40 to 30C
    only)

6
Blackbody Controller Operation
7
Operational Commands
  • Blackbody Modes
  • Constant Temperature
  • Constant Power
  • Set Points
  • Control Thermistor Select
  • Temperature Measurement Range
  • Range Select
  • Autorange On/Off
  • Reset Mode

8
Electronics Error Budget Summary
9
Power Budget Summary
Worst-case for cold side of orbit
10
Model Transient Response
0.14 W Blackbody Power Step
Temperature Error
Time (sec)
11
Model Orbital Response
Blackbody Power
Time (Hours)
Temperature Error
Time (Hours)
12
Measurement Ranges and Self-Calibration
Self-Calibration Point
ADC Output
Thermistor Voltage (V)
13
Self-Calibration Example
Self-Calibration Point
NB
CAL B
ADC Output
NA
CAL A
VA
VB
Thermistor Voltage (V)
14
Self-Calibration
Self-calibration corrects for drift of gain and
offset in electronics Residual error depends
mainly on stability of precision resistors
NA Value at self-calibration point A NB Value
at self-calibration point B VA Voltage at
self-calibration point A (known) VB Voltage at
self-calibration point B (known) K1 Gain
constant K2 Offset constant N Value at
measurement of unknown temperature V Thermistor
voltage at unknown temperature T Blackbody
Temperature
15
Controller Parts Selection Summary
16
Non-Standard Parts
17
Radiation and Shielding
Total mission radiation dose assumed to be 100K
Rad, including X2 safety factor RH108A (Op Amp)
requires additional shielding to 20K Rad
7872RPFS (ADC) and HS9-1840 (Mpx) performance
improves with additional shielding 110 mils
(2.8mm) of additional aluminum shielding is
provided for these parts
18
PWB Thermal Analysis
  • Neglected radiation, assumed conduction only to
    edges at 50C
  • Modeled board as single layer with equivalent
    lateral conductivity based on copper and
    polyimide layer thicknesses
  • Heat flux into board assumed uniform over each
    components area
  • Total power dissipation is 1.2W
  • Components shown total 0.81W, remaining 0.39W
    evenly distributed over remaining board surface
  • Heat to left edge is 0.43W, heat to right edge
    0.77W
  • Maximum temperature is 54C

Wedgelock
Wedgelock
Board layout
Temperature results
19
Parts Derating Summary
Note Maximum PWB temperature 55C
20
Engineering Model Test Set-up
21
Engineering Model Test Results
  • Tested at 25 C only
  • Data Interface
  • Resistance Measurement
  • Temperature Control
  • Preliminary results meet specifications

22
Engineering Model 1 Photograph
23
Flight Unit Acceptance Test Plan
24
Electrical Test Outline
25
Flight Test Set-up
26
Testing Issues
  • SDL Bus Simulator built with commercial
    components may not allow testing of Blackbody
    Controller over entire temperature range.
  • SDL Bus Simulator required for all electrical
    tests
  • SDL Bus Simulator and Blackbody Controller must
    be installed on the common motherboard in close
    proximity
  • Temperature Tests of Blackbody Controller require
    SDL Bus Simulator to operate over the same
    temperature range
  • Motherboard does not allow direct measurement of
    Blackbody Controller power supply currents.

27
Calibration Overview
  • Direct Temperature Calibration Only
  • No Temperature to Resistance or Data to
    Resistance Calibration
  • Would require extremely precise resistance
    references
  • Intermediate calibration allows accumulation of
    errors
  • Interchangeability is not an issue
  • Acceptance Test Resistance Measurements
  • Verify measurement ranges
  • Linearity
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