Difference between revisions of "DFM-17 Radiosonde"

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==Identified Supplementary IC's==
 
==Identified Supplementary IC's==
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File:Stalk pinout mapping.png|Mapping of the pins on the sensor stalk to the connector and their corresponding IC/IO lines. '''''<u>Top of sensor stalk corresponds to bottom of pictured connector!</u>'''''
 
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File:Dfm back pcb no battery.jpg|Back of the DFM PCB without CR123A battery holders
 
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Revision as of 15:23, 17 January 2023

The DFM-17 is a balloon-launched radiosonde manufactured by GRAW Radiosondes GmbH & Co. KG, and used for meteorological sounding.

The label side view of a DFM-17 Radiosonde


Overview

The DFM-17 radiosonde succeeds the DFM-09 radiosonde. Graw began a contract with NOAA in the US to provide radiosondes. As of Late 2021, several sites have made the transition as part of NOAA’s Operational Test and Evaluation (OT&E) program. 45 CONUS sites are expected to use these radiosondes in early 2022. [1]

Specs [2]

  • Weight: 63g
  • Size: 90 x 67 x 44 mm
  • Power supply: 2 CR123A batteries
  • Estimated runtime: ~240 minutes
  • Transmission rate: 1 packet/sec
  • Bandwidth: ~10 kHz (Website lists <12)
  • Frequency range: 400 - 405.99 MHz
  • Modulation: GFSK
  • TX Power: ~100mW
  • Error Correction: Code-spreading, interleaving
  • SoC: STM32F100R8T6B, 24MHz, 8KB RAM, 64KB Flash
  • GPS: U-Blox MAX-M8C-0-10
  • Transmitter: Si4063

Peripheral attachment points

LED's and Buttons

  • Button = PC8
  • LED_Y = PC7
  • LED_G = PC6
  • LED_R = PB12

GPS

  • PA3(RX) = GPS TXD
  • PA2(TX) = GPS RXD

UART via USB Port

  • PA9(TX) = USB D+
  • PA10(RX) = USB D-

Si4063

  • PB2 = CS/nSEL
  • PA7 = SDI
  • PA6 = SDO
  • PA5 = SCLK

Identified Supplementary IC's

IC Part Numbers and Markings
Manufacturer Part Number Description Package Part Marking Datasheet Note
U1 STMicroelectronics STM32F100R8T6B ARM MCU, 24MHz, 8KB RAM, 64KB Flash ARM 32F100R8T6B Mouser
U2, U3, U4, U5, U7 ST STG719 STG719STR Low Voltage 4 Ohm SPDT Switch SOT-23-6 V719 Mouser Analog ADG719 pin compatible equivalent?
U6 Vishay DG636E 0.3 pC Charge Injection, 100 pA Leakage

CMOS ± 5 V / 5 V / 3 V Dual SPDT Analog Switch

636EE Mouser
U8 Texas Instruments SN74LV4053A Triple 2-Channel Analog Multiplexer/Demultiplexer SOT-23-6 LW053A Texas Instruments
U9 Texas Instruments LMV761 Low Voltage Precision Comparator with Push/Pull Output C22A Texas Instruments
U10 Silicon Labs Si4063 High Performance, Low Current Transmitter 40632A

C01Q81

2217

Silcon Labs
U11 u-Blox MAX-M8C-0-10 u-blox M8 GNSS module, ROM, crystal MAX-M8C-0-10 u-Blox
U12 STMicroelectronics M24LR04E-R Dynamic NFC/RFID tag IC with 4-Kbit EEPROM,

energy harvesting, I²C bus and ISO 15693 RF interface

TSSOP8 (DW) 4BEB 8150 STMicroelectronics Needs verification
U13 STMicroelectronics LD series, unsure on specific part 3.3V Low Drop Out Voltage Regulator DFN6 33R Needs verification, appears to provide 3.3V for GNSS
U14 Looks like a high side current monitor amplifier, need more information
U15 ABLIC S-8200A Series, unsure on specific Part Number BATTERY PROTECTION IC FOR 1-CELL PACK VDL Mouser Needs verification, Potentially a Winsok WSTDW01 Battery Protection IC?
U16 AL

W24

In-line with battery power, need more information; chip marking
U17 Connected to USB data lines, likely a UART, isolation, and/or level shifter


Photos

Disassembly


  1. Examine rope, parachute and parachute rigging lines for viability. Neatly organize the flight rigging if usable. Discard if not viable for reuse.
  2. Cut the zip tie surrounding the Styrofoam from the top portion by the rope loop.
  3. Pull the rope loop out, there should be little to no resistance.
  4. Make a slice in the sticker[4] where the two pieces of Styrofoam meet.
  5. Pull apart the two Styrofoam pieces to reveal the circuit board.
  6. Pull the circuit board out. There will be some resistance.
  7. The board is now separated from the Styrofoam shell, reuse if desired.
  8. Pull the two CR123A batteries out, keep or discard them. The board can run off USB power. Batteries are not necessary for development on this board.

Reassembly


  1. Insert two fresh CR123A batteries into the board.
  2. Line up the board to the IO cutouts in the Styrofoam, begin to push into the slots. Make sure the antenna wire comes through.
  3. Press the top piece of Styrofoam into place.
  4. Tape or apply another sticker onto the back label. (Optional)
  5. Insert the plastic rope loop piece.
  6. zip tie the shell together, the zip tie end should end up on the edge nearest to the power button.
  7. Rope on a balloon/drone/kite/etc.. to the rope loop.
  8. Power on the device by pressing and holding the button, you will see a yellow light blink, hold until the light turns solid.

Mini USB Port

The mini USB port on the board does not use the USB protocol for communication, it is a UART bus. However using USB to power the board should not harm the board in theory.

In order to use it, splice a USB cable and wire up a USB<->TTL adapter with the following pins:

  • VBUS: 5 Volts DC
  • D-: TX
  • D+: RX
  • GND: GND


The board will communicate with the official GRAWMET software using this approach. Reverse engineering of the port's protocol is underway, however it is believed to use a similar, if not the same protocol the PS-15 uses.

Hardware modifications

SMA Port to replace antenna:

The DFM-17 has solder pads for an SMA port and a SWD header. An Adafruit Skinny SWD SMT connector and a generic SMA connected was used in the photo.

Minimizing transmit range:

As amateurs we are not licensed to transmit in the 400-406MHz band, so for testing purposes one should perform this mod. Unsolder the antenna wire and take two 100 ohm resistors and twist them in parallel, then solder them to the center pad and one of the side pads on the SMA footprint. This creates a 50 ohm dummy load for the Si4036 to transmit into. The range is reduced to a couple tens of feet. Also if you are running a radiosonde_auto_rx instance, don't forget to turn it off during testing to avoid feeding erroneous data to Sondehub!




Developing and Programming the board

A very crude diagram showing the standard SWD pinout overlaid onto the DFM-17 board


When lab testing, you can power the board from the USB header. It also appears to run fine supplying 3.3V to the SWD port(STLink clones do this).


The board uses a STM32, and requires a ST-Link to program. The process used to upload code to the MCU is the same as the Vaisala RS41 radiosonde, you will need to solder and connect the VTRef(3.3V), Ground, SWDIO, SWDCLK and RST pins to your ST-Link.

The board can run without external power being supplied when programming. This board has read-out protection enabled similar to the RS41 and this must be disabled before you can flash firmware to the board.