* Fig 3
   *  C
      * Leafout_Creaseline_Force_Tests - Sheet1.csv
         * Force required to transition a four unit cell origami structure on different film thicknesses and various cut patterns, without electronics or actuation system. Values measured in mg and converted to force.
   * D
      * Leafout_unitCells_dropTests - Open.csv
         * Number of flips observed when dropping designs with various numbers of unit cells in the tumbling state from 2 m.
   *  E
      * Lateral_displacement_wind_test - Sheet1.csv
         * Lateral displacement when dropped from a height of 0.5 m in the tumbling state.
* Fig 4 
   * B
      * 3D models showing the actuator changing the shape of the origami from the flat (tumbling) state to the folded (stable) state.
         * Stable State.stl
         * Tumbling State.stl
   * D
      * Cap Volts-force vs time_Zenodo  - Sheet1.csv
         * Waveform showing the voltage of the capacitor as it discharges into the actuator and the resulting force the actuator produces forces up to 250 mN when accelerating the magnet upward.
   * E
      * Cap mass vs Force_ Zenodo - Sheet1.csv
         * Actuator force achieved for capacitors of different equivalent series resistance and capacitance versus component mass.
   * F
      * Magnet attraction force test - Sheet1.csv
         * Upward force exerted by the second magnet versus their separation gap.
* Fig 5 
   * C
      * Waveforms illustrate microcontroller cold start followed by charging and triggering the actuator for transitioning the structure.
         * tek0000CH4.csv - Solar cell Voltage
         * tek0001CH1.csv - C_STORE Voltage
         * tek0001CH2.csv - MCU Voltage
         * tek0001CH3.csv - C_ACTUATOR Voltage
         * tek0001CH4.csv - V_SWITCH / V_TRIG
   *  D, E 
      * leafout_power_measurements - outdoor_solar_raw_total_trials.csv
         * Time required to cold start the microcontroller at varying light levels. Time required to charge up the capacitors to transition at varying light levels. 
   * F
      * Solar vs packet throughput - Sheet1.csv
         * Achievable Bluetooth throughput at varying light levels.
   *  G
      *  Packet delivery rate vs range_Zenodo - Sheet1.csv
         * Bluetooth packet delivery rate versus range.
* Fig 6 
   * A
      * 20m drop_Zenodo - Sheet1.csv
         * Outdoor drop tests from 20 m for tumbling state and the stable state across wind conditions.
   * B
      * 40m drop_Zenodo - Sheet1.csv
         * Outdoor drop tests from 40 m showing distance for traveled tumbling state and the stable state and when the microflier transitions in mid-air.
* Fig 7 
   * B
      *  in-air Altitude and Presure_Zenodo  - Sheet1.csv
         * Real-time pressure sensor readings sent via Bluetooth showing.
   * C
      * In-Air temp_Zenodo - Sheet1.csv
         * Real-time temperature sensor readings sent via Bluetooth.
   * D
      * On Ground Sensor_Zenodo - Temp.csv
         * Temperature readings from a 3 day outdoor deployment.
   * E 
      *  On Ground Sensor_Zenodo - Pressure.csv
         * Pressure readings from the 3 day outdoor deployment.
* Fig S1 
   * B 
      * Movement of center of pressure along the y-axis versus time. 
         * Experiment1_closed_drag_coefficient_moment_L.npz
         * Experiment2_opened_drag_coefficient_moment_L.nz
         * PIV_figure_pressure_moment.ipynb
            * Code for processing and producing figure
   * C
      * Time averaged 2D velocity profiles visualizing the magnitude of the flow field in the wake immediately above the flier.
         * Experiment1_closed_mean_field_L.npz
         * Experiment1_closed_origin_L.npz
         * Experiment2_opened_mean_field_L.npz
         * Experiment2_opened_origin_L.npz
         * PIV_Figure_mean_velocity.ipynb
            * Code for processing and producing figure
* Fig S2
   *  transition-force_vs_payload_rawData - Zenodo - Sheet1.csv
      * Origami transition force versus payload.
* Fig S6
   * Solar irradiance to current_Zenodo - Sheet1.csv
      * Solar irradiance to current.
* Fig S8
   * A
      * Reference temp vs Microflier Temp Zenodo - Sheet1.csv
         * Day long comparison of temperature sensor data from our deployed origami microflier and a reference.
   * B
      * microflier sensor and the reference - Sheet1.csv
         * Linear regression between the microflier sensor and the reference.
* Fig S9 B
   * Magnet_pickup_test - Sheet1.csv
      * Average height that the microflier is attracted to the pickup system.
* Fig S10
   * Terminal Velocity (m_s)_Vs_Number of Cells_Zenodo - Sheet1.csv
      * Average terminal velocity of the leaf-out design with three through eight unit cells when dropped in the tumbling state from a height of 2 m.
* GliderFinal-main-10-4
   * Nord NRF code for Microflier
* circuit_LeafoutGlider-2023-05-22_152807
   * KiCAD Circuit design files