1. P14452: Subsystems Design Review

2. Review Where we left off

3. Updated Engineering Specifications

4. Previous Functional Decomposition

5. Capture Data

6. Store Data

7. Power Device

8. Protect Device

9. Chosen Concept

10. Materials Analysis Building a Better Box

11. Plan Comparisons of Materials Acetal Resin (Delrin®-150) Polysulfone Polyester (Ertalyte® PET-P) Aluminum 6061 Applied Loads 100psig applied to external surfaces 200F applied to bodies

12. Acetal Resin (Delrin®-150) Properties Max Operating Temp 180F Yield Strength 10400psi Modulus 450ksi CTE 278μin/in-°F Cost: 1.5”x6”x6” sheet $35.71 Max Deformation.060” Max Stress ? ANSYS Simulation

13. Polysulfone (PSU) Properties Max Operating Temp 285F Yield Strength 10900psi Modulus 390ksi CTE 29.4μin/in-°F Cost: 1.5”x6”x6” sheet $147.83 Max Deformation.006” Max Stress 6862 psi ANSYS Simulation

14. Polyester (Ertalyte® PET-P) Properties Max Operating Temp 210F Yield Strength 12400psi Modulus 490ksi CTE 33μin/in-°F Cost: 1.5”x6”x6” sheet $48.57 Max Deformation.007” Max Stress 9744 psi ANSYS Simulation

15. Aluminum 6061 Properties Max Operating Temp 500F Yield Strength 40000psi Modulus 1000ksi CTE 13.1μin/in-°F Cost: 1.5”x6”x6” sheet $53.44 Max Deformation.003” Max Stress ? ANSYS Simulation

16. Weight Density: Acetal:.0513 lb/in 3 Polysulfone:.0448 lb/in 3 Polyester:.0361 lb/in 3 Aluminum:.0975 lb/in 3 Mass: Acetal:.0671 lb (30.4g) Polysulfone:.0586 lb (26.6g) Polyester:.0472 lb (21.4g) Aluminum:.1275 lb (57.8g) Volume: 1.3075 in 3

17. Other Properties Thermal Conductivity Acetal: 2.5 BTU-in/hr-ft²-°F Polysulfone: 3 BTU-in/hr-ft²-°F Polyester: 2 BTU-in/hr-ft²-°F Aluminum: 1160 BTU-in/hr-ft²-°F Electrical Resistivity Acetal: 10 15 ohm-cm Polysulfone: 10 16 ohm-cm Polyester: 10 12 ohm-cm Aluminum: 10 -6 ohm-cm

18. Pugh Analysis DelrinPSUPETAl Strength- DATUMDATUM ++ Operating Temp --+ Cost+++ Weights+- Thermal Conductivity ss- Electrical Resistivity ss- Total1/23/13/3

19. Case Geometry The Best Things Come in Small Sizes

20. PCB Dimensions Show 3D Rendering

21. Mounting Two part solution Flange Base Through Hole in each corner Can be used to mount directly Adapter Plates Attach to flange base Allow for Mounting on existing holes Allow for adhesive, zelcro, magnets, etc.

22. Generalized Design Rectangular Prism 1-3 Ports for Analog I/O 1 Micro-USB Port Charging Data Access Flange Base Fasten from Bottom Locks access to inside of device when mounted Provides Mounting Holes

23. Microcontrollers Choosing a Better Brain

24. Criteria 1: ADC Accuracy Bit Width# of ValuesLSB (Accuracy) 10102419.53 mV 1240964.88 mV 14163841.22 mV 1665536305 uV 1826214476.3 uV 20104857619.1 uV 24167772161.19 uV

25. Criteria 2: ADC Type Successive Approximation 10-12 bit Accuracy Fast Sample Rate (>200kS/s) Requires External Low-pass Filter Costs Board Space 3 Op-amps (Bi-Quad) Resistors and capacitors Sigma-Delta 12-24 bit Accuracy Slow Sample Rate (<200kS/s) No External Low-pass Filter Filter is part of sampling process Must be careful of bit width effect on frequency range

26. Criteria 3: Serial Throughput (SD) Bit WidthBits/s (1 Ch)*Bytes/hr (1 Ch)*Bits/s (4 Ch)*Bytes/hr (4 Ch)* 10100k42.915 MB400k~172 MB 12120k51.498 MB480k~206 MB 14140k60.081 MB560k~240 MB 16160k68.885 MB640k~276 MB 18180k77.248 MB720k~309 MB 20200k85.831 MB800k~345 MB 24240k102.997 MB960k~412 MB * at 10kHz sampling rate

27. Criteria 4: I/O Capability SD Card 1 SPI interface 1 Serial Clock USB Data Access 1 USB UART ADC 1-4 ADC Channels GPIO 1 Digital (SD) >2 Digital for Hardware Sampling Rate (per channel)

28. Criteria 5: Processor Speed ADC requirement 10000 Samples/s per Channel May take more than 1 cycle per sample to read from ADC Estimated Minimum Speed 40000 Samples/s (4 Channels) 2 Cycles per Sample Read 112 Cycles per Sample Write 5 Bytes Data 1 Bytes Channel ID 5 Bytes Timestamp 2 Bytes “,” 1 Byte CR 4.56 MHz

29. Microcontrollers STM32F373 32-bit ARM M4F (72 MHz) Floating Point DSP Instructions 1-3 Sigma-Delta ADC 16-bit 16.66 kHz max per channel DMA Interface ADC Synchronization 3 SPI (18 Mbit/s) Up to 84 GPIO 1 USB UART (12 Mbit/s) MSP430F67XX 16-bit RISC ( 8-25 MHz) No Floating Point No DSP Instructions 3 Sigma-Delta ADC 24-bit 31 kHz per channel max DMA Interface ADC Synchronization 2 SPI (5 Mbit/s) 52 or 72 GPIO No USB

30. Input Conditioning The Large Signal Problem

31. Attenuation Circuit Use resistor bridge to reduce the voltage for input to microcontroller Set a unity gain Also decreases the current going into the uC

32. Simplified Circuit

33. Final Circuit

34. Attenuator Non-ideality

35. Power Source Phenomenal Cosmic Power. Itty Bitty Living Space.

36. LiPo vs. Ultra Capacitor Ultra Capacitor (KEMET FT0H105ZF) Diameter = 21.5mm (0.846in) Height = 13mm(0.512in) Area= 1502mm^3 Max Voltage 5.5V 1F capacitance Max current is 1.5mA for 30 mins Weight = 10 grams Price 1  $4.23, 10  $38.03 KEMET FT Series pages 2-4 LiPo Battery (All-battery.com 602025) Base: 25mm x 20mm Height: 6mm Area=3000mm^3 Voltage = 3.7V 240 mAh Max Current is 48mA for 5 Hours Weight = 4 grams Price for 5-10  $3.25 each http://www.all-battery.com/polymerli- ionbattery37v240mah602025.aspx http://www.all-battery.com/polymerli- ionbattery37v240mah602025.aspx

37. LiPo Charging Spark Fun Power Cell – LiPo Charger/Booster Micro USB charging $19.99 breakout board for testing Eagle Files Available for PCB layout

38. Schematic for LiPo Charging and Booster https://www.sparkfun.com/products/11231

39. Components Required LiPo Charger and Booster MCP73831/2: LiPo Charging IC Can get free samples TPS61200: 5 volt, 600mA boost converter Can get free samples Used for powering sensors and other components JST connector $0.95 Micro USB SMD Connector $1.95 Resistors and Capacitors <$2.00

40. Action Items The Road Ahead

41. Mechanical Action Items Materials and Modelling Choose Final Material Solid Modelling Small Device Large Device Ansys Simulations Small Device Large Device Sensor Characterization Catalog Existing Sensors in Compressor Centralized Collection of Data Sheets Reference Card for Sensors Voltage Range Current Output Frequency Ranges Optimal Sampling Rate Voltage to Unit Conversion Factor

42. Electrical Action Items PCB Finalize Electrical Schematics Small Device Large Device Finalize PCB Designs Small Device Large Device Final Component Selection Analog Analysis Attenuator Final Design Differential Amplifier Precision Voltage Reference Input Voltage Clamping Overvoltage Protection LiPo Charging Circuitry

43. Computer Action Items Algorithms Digital Filtering Sample Ordering Timestamp Calculation Processor Initialization Routines Processes Sampling Procedure Channel Switching Multiple Sampling Rate Switching DMA transfers Offload SPI Offload ADC Processor can focus on filtering and coordinating

44. Questions? El fin.