Mont Alto Projectile Project (M.A.P.P.) BU Novel Magnetometers Flight Experiment

1. Mont Alto Projectile Project (M.A.P.P.)BU Novel Magnetometers Flight Experiment Critical Design Review Penn State Mont Alto Boston University 12/17/2008

2. MAPP Team Kylie Flickinger – Mechanical Engineering Adam Kuhlman – Data Acquisition William K. McDannell Jr. – Software Chris Small – Strain Gauge Board Robert Stottlemyer – Team Leader Tim Svirbly – Test Equipment Development RockSat CDR

3. BU Mag Dog Team • Sensors – Aichi – Shawn Doria • Sensors – Honeywell – John Gancarz • Power – Tracy Thai • Rabbit Controller – Andy Lee • Mechanicals – Jim Thumber • Software/Simulations/Analysis – TBD • Nanosat teams join after January 30 RockSat CDR

4. MAPP Science The purpose of this experiment is to investigate the mechanical stresses in an elastic structure during the flight of a sounding rocket. The structure proposed consists of a circular plate, the deck plate, which is supported by four longerons, which connect in turn to circular plates at either end of the longerons simulating a payload section of previous sounding rocket flights. A dummy mass is attached to the center of the deck plate. During the flight, dynamic loads in the axial and lateral directions will cause the deck plate to deflect. The resulting deformation will be measured at selected points using strain gauges connected to electronic boards to obtain time-varying voltage signals which in turn will be digitized and stored for later analysis. The obtained data will be compared to theoretical predictions. Careful pre-flight calibration of the entire data stream will be conducted. RockSat CDR

5. Novel Magnetometers Flight Experiment - Science • Design, assemble, and test two COTS, solid state 3-axis magnetometers with controller, data storage and power: • Honeywell HMR2003 - anisotropic magneto-resistance • Aichi Micro Intelligent AMI302 - giant magneto-impedance • Compare directly the X,Y,Z flight readings of both sensors • Measure EMI from the chips’ bias straps (Honeywell) and bias coils (Aichi). • Honeywell device proposed for U. Colorado small satellite design (2003). We have found no other evidence of its use in space flight. • Aichi chip under study by US Navy for navigation of autonomous marine vehicles. We have found no record of the Aichi chip being used in space. RockSat CDR

6. Mechanical Subsystems MAPP • Bottom Plate • Deck Plate • Top Plate • Longerons • Test Weight • Trays for Boards • Braces • Electrical Subsystems MAPP • G-Switch + Latched Relay • Battery and Regulation • Strain Gauge Boards • Strain Gauges • Controller + A/D conversion • Data Storage Subsystem Requirements • Mechanical Subsystems BU • Main PCB • Rabbit daughter board • Battery pack • Electrical Subsystems BU • G-Switch + Latched Relay • Battery and Regulation • Honeywell magnetometer • Aichi magnetometer • Controller + A/D conversion • Data Storage RockSat CDR

7. Honeywell Aichi Block Diagrams Data Card Controller A/D Strain Gauge Power Latched Relay G-switch Launch safing Controller A/D Magnetometers Data Card Power G-switch Launch safing RockSat CDR

8. Assembly Mont Alto RockSat CDR

9. Test weight RockSat CDR

10. Top disk RockSat CDR

11. Bottom Disk RockSat CDR

12. Deck plate RockSat CDR

13. MAPP Strain Gauges • After testing in SolidWorks, we determined that the deck plate would not deform enough for the strain boards that we built for the USERS program to amplify the signal enough to get meaningful data using metal strain gauges. After research, we decided to use semi-conductor strain gauges, which have a gauge factor of ~60 times that of a metal foil strain gauge. We will implement them in a configuration that would both double signal output and reduce concerns about temperature sensitivity. Using this configuration should allow us to use our boards from the USERS program with only minor changes. RockSat CDR

14. Strain Gauge (Up Close) RockSat CDR

15. G-Switch + Latched Relay RockSat CDR

16. MAPP Controller + Memory • Memory Needs : 12 Analog Signal Streams each digitized at ~250 samples/second to be sampled for 750 seconds at 2 bytes per sample = 4.5 Megabytes • Data stored on a SD card inserted into Miniboard (45mm x 55 mm) - www.futurlec.com/mini_sc.shtml standard SD or SPI communication. 3 Volt power • Microcontroller Board – www.microchip.com/wwwproducts/devices.aspx?ddocname=en024691 Model : PIC24HJ256GP206 , 18 channels 12 bit A/D conversion at up to 500 ksps, 2-UART,2-SPI, 2-12C digital communication, 3 to 3.6 Volt power with on-chip 2.5 Volt power regulator, size 1.0”x2.2” . Programming language C RockSat CDR

17. Special Requirements • MAPP Special Requirements • Shift in center of mass along length axis on rocket • BU Special Requirements • Minimize magnetic materials and fields RockSat CDR

18. MAPP Commands and Sensors • Always On – Triggered by the G-Switch • Turned off by microcontroller before splash down • 12 Analog Signal Streams each digitized at ~250 samples/second to be sampled for 750 seconds at 2 bytes per sample = 4.5 Megabytes • Data stored on a SD card Miniboard (45mm x 55 mm) - www.futurlec.com/mini_sc.shtml • Microcontroller Board (protopic 28) – 1.0” x 2.2” – www.microchip.com/wwwproducts/devices.aspx?ddocname=en024691 Model : PIC24HJ256GP206 , 18 channels A/D conversion, on-chip 2.5 Volt power regulator • Strain Gauge: Vishay or Semiconductor (to be decided) • Data Acquisition Controlled by Microcontroller initiated by power on RockSat CDR

19. MAPP Test Plans • Mechanical Stress Distribution • SolidWorks • Thin Plate Theory • Static Force Rig (similar to the one we used for USERS) • G-Switch and Latched Relay • Spring loaded launch in a controlled setting • Ensure compliance with no-volts requirement when integrated with power supply • Strain Gauges • Temperature sensitivity • Circuitry and Signal Strength – simple beam test • Compare to metal foil strain gauges • Calibration • Data Acquisition/Storage • Store and retrieve data • All electronics: Burn in period RockSat CDR

20. MAPP Timeline • By the end of fall semester (12/19/08) • Critical design review completed • Begin ordering parts • Wrap up design phase • Over Christmas Break (12/19/08 – 01/12/09) • Continue ordering parts • Begin planning build phase • Beginning of Spring Semester (01/12/09) • Meet to plan build phase • Take an inventory of parts • Between (01/12/09 – 03/15/09) Build Phase • Manufacture circuit board for data collection • Alter strain gauge boards • Manufacture testing rigs—Static force rig like we used for USERS, Spring mechanism to test G-Switch • Manufacture G-switch • Manufacture plates, longerons, alter dummy weight from USERS, braces, and housing for battery and g-switch. • Between (3/15/09 – 4/25/09) Testing Phase • Test performance of Semiconductor Strain Gauges—Compare to metal foil strain gauges. Also test temperature drift. • Static force rig similar to the one we used for testing for the USERS project • Test performance of G-Switch and power supply • see that it meets launch safing no volts requirements. • Use spring mechanism to test the performance of the “ball and tube” part of the G-Switch • Test performance of Data Acquisition unit • Burn in period for electronics • Preliminary Integration Phase (4/25/09 – 5/3/09) • Assemble structure • Attach strain gauges to test points in structure • Integrate electronic components—manufacture wire harnesses • Have structure ready to install in can • Finals week (5/4/09 – 5/8/09) • See you in June! Launch at Wallops RockSat CDR

21. MAPP Parts List Mechanical parts # Item Status # Item Status 4 Brace A designed 1 Test Weight Completed 4 Brace B designed 4 Trays Completed 8 Brace C designed 4 Longeron designed 1 Bottom Disk designed 1 Deck Plate designed 1 Top Disk designed • Not at the nut and bolt level… just major hardware that will be purchased or built in house • Lead times (This can make or break a project) • Distributors • Manufacturers • Cost (Don’t forget to consider shipping and tax) RockSat CDR

22. MAPP Parts list, cont. Electronic Parts : # Item Status 2 Strain gage board Modification needed 1 Power regulator board Modification needed 1 G-switch and associated electronics needs more design work 1 data acquisition/storage + controller needs more design work RockSat CDR

23. MAPP Budget RockSat CDR

24. RockSat Payload Canister User Guide Compliance (MAPP & BU) Mass estimate includes everything shown in slide 16 . Missing are the electronic boards ( 4 of 4”x4” ) for MA and electronic boards and battery for BU m = 10.86 lbs (< 12.75, the heavy test mass can be reduced) Center of mass 0.03” off axis and 1.06” below geometric center. Because electronic boards and tray for the BU experiment have not been included, the center of mass will move slightly closer to the geometric center. Entire structure fits into a cylinder of 9” (<9.2) diameter and 9.275” (<9.4) height leaving 0.125” for washers. Connection with 5 bolts to top and bottom bulk head , respectively, is provided. RockSat CDR

25. RockSat Payload Canister User Guide Compliance– cont. • Payload Activation a battery , a G-switch, and shorting wires to Wallops shorting plug form a complete loop with electric current flowing only if both the G-switch and shorting plug are in closed position simultaneously. Once current is flowing a circuit consisting of a second battery (ies) and all electronic boards is activated using a solid-state latched relay and switch transistor. This second loop maintains itself even when the G-switch subsequently falls back into its open position (during ballistic flight phase). RockSat CDR

26. Shared Can Logistics Plan • Boston University (Mike Ruane) • Penn State Mont Alto (Zig Herzog) Sharing mechanical structure but independent power supply, controller, data acquisition, and data storage. Possibility of future sharing of these items is not excluded . RockSat CDR

27. Team Management Dr. Siegfried Herzog Penn State University at Mont Alto Assistant Professor of Mechanical Engineering 1 Campus Drive Mont Alto, PA 17237 Tel (717)-749-6209    Fax (717)-749-6069 E-Mail: hgn@psu.edu Dr. Michael Ruane Professor, ECE Dept., Boston University 8 St. Mary's Street, Boston, MA 02215 Phone: 617-353-3256 617-353-6440 fax E-Mail: mfr@bu.edu RockSat CDR

28. MAPP Conclusions • Lab space available • Students are nervous but excited • We have some previous experience with the USERS program and can re-use some parts • We aim to finish by the end of April (end of the spring semester) • Looking forward to beach time!  RockSat CDR

29. BU Subsystems • Sensor 1 Aichi • Sensor 2 Honeywell • Power (Battery + Regulation) • Controller • Sequencing of sensors • Data A/D conversion • Storage to SD card RockSat CDR

30. BU – Aichi AMI302 Magnetometer Sensing technology Based on Magneto-Impedance effect of amorphous magnetic wire Range of measurable magnetic flux density: -2 to +2 gauss 3 sensors for length, width, and height (X, Y, Z) Inputs and Outputs: Unit: mm RockSat CDR

31. BU – Aichi AMI302 Magnetometer • Supply Voltage: -0.3 to +6.5 VDC • Maximum Supply Current: 200 mA • Approximately 1% duty cycle on this peak current • Operating Temperature: -20 to +85°C • Magnetic Characteristics • Operating Test Conditions • Ambient Temperature: 25°C • Power Supply: 3 VDC • 10 μF ceramic capacitor between Power Supply and Ground RockSat CDR

32. BU - Honeywell HMC2003 Magnetometer Sensing technology Anisotropic magneto-resistance Range of measurable magnetic flux density: -2 to +2 gauss 3 sensors for length, width, and height (X, Y, Z) One output for each direction (Xout, Yout, Zout) RockSat CDR

33. BU - Honeywell HMC2003 Magnetometer • Supply Voltage: 6 to 15 VDC • Maximum Supply Current: 20 mA • Operating Temperature: -20 to +85°C • Magnetic Characteristics • Operating Test Conditions • Ambient Temperature: 25°C • Power Supply: 12 VDC • Set/Reset switching is active RockSat CDR

34. BU - RCM4300 RabbitCore 1GB of storage – mini-SD memory card Runs at 58.9MHz 20 parallel digital I/O lines 8 channel analog input with 12 bit resolution Max asynchronous transfer rate =Clk (58.9MHz)/8 4 PWM registers, 10 bit counter, priority interrupts Input/Output: 3 Inputs from Aichi - X axis / Y axis / Z axis output from Aichi 3 Inputs from Honeywell - X axis / Y axis / Z axis output from Honeywell RockSat CDR

35. BU - RCM4300 RabbitCore cont. Aichi Use timer to time selection of outputs for x, y, z axes Iterate outputs from RabbitCore to read different axes on Aichi Different channels for x, y, and z axes Take input and pass through A/D converter from each Aichi channel Store converted values onto SD flash memory for future use Honeywell Use timer to constantly poll Honeywell for all x, y, and z axes nearly-simultaneously Store data from each axis on a separate place on the SD flash Each axis is read from a separate output pin on Honeywell chip Use A/D converter to store as value and store converted value on flash Both chips User timer to select which chip is off for EMI comparisons RockSat CDR

36. BU – Sensor Schematics RockSat CDR

37. BU - Science Experiment Timing Normal 1 H A M 5 Mins EMI 1 ~H A M 30 Sec Normal 2 H A M 3 Mins Start at Launch Key: H - Honeywell A - Aichi M - Memory(rabbit) EMI - Electromagnetic Interference EMI 2 H ~A M 30 Sec Safe ~H ~A ~M End Normal 4 H A M 10 Mins Normal 3 H A M 3 Mins EMI 3 ~H ~A M 30 Sec RockSat CDR

38. BU - Data Flows • 2 sensors, 4 data sources, housekeeping • 12 b/sample on Rabbit RCM4300 • Slow change in Earth’s field over flight • Changes from spin of rocket (<10 Hz) • Sample 10 pts/cycle or 100 Sa/s • Estimated flight 22.5 min or 1350 s • 135k Sa x 4 x 12b/Sa = 6.48 Mb = 0.8MB • Well within low-end SD card capacities RockSat CDR

39. BU Testing Plans • Electrical systems operation • Timing test for sequencing • DAQ test with sensors • SD card storage and retrieval • Sensor operation • Earth field testing • Helmholz coil testing of boards • Power operation • Charging/discharging • Voltage regulation and distribution RockSat CDR

40. BU - Parts & Vendors • Aichi AMI302 (3 on hand from Aichi; two week order time) • Honeywell (2 on hand; distributors; 2 week order time) • PCB fab - turnaround (5 business days) • PCB Assembly for Aichi (10 business days) • Rabbit Core 4300 (Dev kit on hand) • Miscellaneous DigiKey/Newark parts RockSat CDR

41. BU - RockSat Payload Canister User Guide Compliance • Sensor PCB ~15 cm x 15 cm x 2 cm; < 150 g • Rabbit PCB ~ 5 cm x 8 cm x 1 cm; <100 g • Battery ~ 6 cm x 10 cm x 2 cm; <150 g • (Easily reside in ½ canister or even ¼ height) • Will follow G-switch and Rocket wire protocol • Independent of MAPP system except CG RockSat CDR

42. Shared Can Logistics Plan • Penn State Mont Alto - Boston University • Each system is independent • Structural interfacing (PSMA) BU Cards + Batt RockSat CDR

43. BU Mechanical Layout Top Plate Mont Alto MAPP Alternate: Trim one corner to avoid Cable channel and align standoff Holes accordingly. RockSat CDR

44. BU Timeline RockSat CDR

45. BU Budget RockSat CDR

46. BU Conclusions • BU Mag Dogs Team is closing out its semester and catching up to the RockSat schedule • We have an enthusiastic group of students, a lab space for work, and a Nanosat team becoming available in January • Our experiment is building on a sensor board from USERS and a microcontroller DAQ system RockSat CDR

47. Appendices – Backup Slides RockSat CDR

48. Management Dr. Michael Ruane Professor, ECE Dept., Boston University 8 St. Mary's Street, Boston, MA 02215 Phone: 617-353-3256 617-353-6440 fax E-Mail: mfr@bu.edu Dr. Siegfried Herzog Penn State University at Mont Alto Assistant Professor of Mechanical Engineering 1 Campus Drive Mont Alto, PA 17237 Tel (717)-749-6209    Fax (717)-749-6069 E-Mail: hgn@psu.edu RockSat CDR

49. Housing , Battery + G-switch RockSat CDR

50. Strain Gauge Circuit RockSat CDR