User manual - STMicroelectronics...User manual UM2116 - Rev 8 - July 2020 For further information contact your local STMicroelectronics sales office. 1 Demonstration kit description

IntroductionThe STEVAL-MKI109V3 motherboard provides users with a complete, ready-to-use platform for the evaluation ofSTMicroelectronics MEMS products.

It includes a high-performance 32-bit microcontroller which functions as a bridge between the sensors and a PC, on which youcan download and run the graphical user interface (GUI) or dedicated software routines for customized applications.

The board features a DIL24 socket to mount all available adapters for both digital and analog output MEMS devices.

STEVAL-MKI109V3 Professional MEMS Tool motherboard for MEMS adapter boards

UM2116

User manual

UM2116 - Rev 8 - July 2020For further information contact your local STMicroelectronics sales office.

www.st.com

1 Demonstration kit description

The Professional MEMS Tool is a complete demonstration kit for digital and analog MEMS sensors. Thanks to itsDIL24 connector, a wide range of MEMS adapter boards can be used.

Figure 1. Demonstration board block diagram

The Professional MEMS Tool demonstration kit is based on the STM32F401VE microcontroller and can beconnected to a PC via USB. Data from MEMS sensors connected to the board can be read through the PC GUIprovided with the kit.The Professional MEMS Tool also implements the device firmware upgrade (DFU) feature, so it can bereprogrammed with a new firmware release without the need to use a programmer (see www.st.com/mems).The Professional MEMS Tool integrates:• Six LEDs:

– two LEDs connected via FET buffers to the interrupt pins of digital adapters– a power/USB LED– three general-purpose LEDs for firmware state indication

• Three buttons:– two user buttons on a dedicated GPIO of the microcontroller– a microcontroller reset button

All the MEMS adapter pins are available on board connectors J1 and J3.

UM2116Demonstration kit description

UM2116 - Rev 8 page 2/41

https://www.st.com/mems

Figure 2. Top silkscreen of the Professional MEMS Tool kit


UM2116 - Rev 8 page 3/41

Figure 3. Top view of Professional MEMS Tool kit

Figure 3 highlights some of the main components on the top layer of the Professional MEMS Tool kit.1. Button BT3 is used to reset the STM32.2. Button BT2 connected to STM32 GPIOs and available to the user. To enter DFU mode:

a. press buttons BT3 (Reset) and BT2 togetherb. first release BT3 and then release BT2

3. BT1 connected to STM32 GPIOs and available to the user.4. Jumpers J13 (VDD) and J14 (VDDIO) allow the user to measure the sensor current consumption by

connecting a multimeter in series with their terminals.5. Jumper J10 is used as a general purpose input to manually set certain features for several MEMS adapters.6. Jumper J12 is used as a general purpose input to manually set certain features for several MEMS adapters.7. Jumper J11 is used to set the self-test feature during testing of Professional MEMS Tool PCB.8. Jumper J7 is used to select either JTAG (JP7 open – NRST control not allowed from programming

connector J6) or SWD mode (JP7 shorted – NRST control allowed from connector J6).9. J6 connector can be used to reprogram the STM32 and debug the code through the JTAG or SWD

protocols.10. Jumper J4 can be used to directly supply the board (from 4.5 V to 5.5 V) instead of through the USB

connector.11. LED D6 lights up when the board is powered.12. J8 connector can be used for UART RX/TX communication.


UM2116 - Rev 8 page 4/41

13. LEDs D1, D2, and D3 are general-purpose LEDs used to indicate firmware states; e.g.:a. LED D3 YELOW light up when specific firmware is selected from those availableb. LED D2 RED on indicates that the microcontroller is properly configured for communication with the

sensorc. LED D1 GREEN blinks according to the sensor data rate selected

14. J9 connector can be used for general purpose SPI bus.15. LEDs D4 and D5 are directly connected to the interrupt pins of the MEMS digital adapters (if available on the

sensor mounted on the adapter board).Figure 4. How to plug the DIL24 adapter on STEVAL-MKI109V3 shows how to plug the DIL 24 adapter MEMSmodule on the Professional MEMS Tool. VDD and VDDIO are in the top left corner (pins 1 and 2) and GND is inthe bottom right corner (pin 13).

Figure 4. How to plug the DIL24 adapter on STEVAL-MKI109V3


UM2116 - Rev 8 page 5/41

2 Professional MEMS Tool board installation

The software packages can be downloaded from the st.com website; it is arranged in the following directorystructure:• DRIVER: it contains the installation package for the USB drivers needed to connect the Professional MEMS

Tool board to the PC. No driver is needed on Linux and Mac OS platforms, so this directory is included in theWindows installation package only. On Windows 10, it is suggested to use Microsoft native drivers and avoidany additional installation.

• FIRMWARE: it contains .dfu and .bin files for firmware upgrade.

2.1 Hardware installation (Windows® platforms before Windows 10)

• For Linux® and Mac OS® platforms, no driver installation is required.• For Windows platforms, install the STM32 virtual COM port driver by running VCP_V1.5.0_Setup.exe in the

DRIVER folder of the Windows installation package and follow the instructions.

Once the driver is installed, connect the demonstration kit board to a free USB port. A confirmation messageshould appear.

Figure 5. Successful device driver installation

Confirm which COM port has been assigned to the board: right click on My Computer and select Manage, thenselect Device Manager and scroll through the list to Ports (COM & LPT).

Note: The STM32 virtual COM port driver for Windows platforms and related documents are packaged with the STSW-STM32102 software download at www.st.com

Figure 6. Virtual COM port assignment

UM2116Professional MEMS Tool board installation

UM2116 - Rev 8 page 6/41

2.2 Firmware upgrade

The MEMS STEVAL-MKI109V3 demonstration board can be reprogrammed by a dedicated application via USB,in accordance with the DFU class specification defined by the USB Implementers Forum.. This directreprogramming of the microcontroller is particularly suited to USB applications where the same USB connectorcan be used both for the standard operating mode and the reprogramming process.To configure the Professional MEMS Tool board in DFU mode:• press button BT2 before supplying the board and release it when LED D6 lights up• or

1. press BT3 (Reset) and BT2 together2. release BT3 followed by BT2.

Led D6 will light up and the device should appear in Windows Device manager as “STM device in DFU mode”.

2.2.1 Firmware upgrade on WindowsOn Windows platform, we recommend the use of the multi-platform STM32CubeProgrammer software. Refer touser manual UM2237 on www.st.com for further details.

Note: The STM32CubeProgrammer software uses *.bin source files for firmware upgrade.

Note: In case you have installed older DfuSe software on your machine, you must uninstall it before installing theSTM32CubeProgrammer software.

2.2.2 DFU on Linux®The DFU program for Linux operating systems is dfu-util. The procedure for Ubuntu Linux operating systems isdescribed below.

Step 1. Open a terminal and run (with sudo to ensure the correct permissions):sudo apt-get install dfu-util

Step 2. Create a udev rules file:sudo gedit /etc/udev/45-Professional MEMS Tool.rules

Step 3. Fill it with the following content:

# 0483:5740 - STM32F4 in USB Serial Mode (CN5)ATTRS{idVendor}=="0483", ATTRS{idProduct}=="5740",ENV{ID_MM_DEVICE_IGNORE}="1"ATTRS{idVendor}=="0483", ATTRS{idProduct}=="5740",ENV{MTP_NO_PROBE}="1" SUBSYSTEMS=="usb",ATTRS{idVendor}=="0483", ATTRS{idProduct}=="5740",MODE:="0666"KERNEL=="ttyACM*", ATTRS{idVendor}=="0483",ATTRS{idProduct}=="5740", MODE:="0666"# 0483:df11 - STM32F4 in DFU mode (CN5) SUBSYSTEMS=="usb",ATTRS{idVendor}=="0483", ATTRS{idProduct}=="df11", MODE:="0666"

Step 4. Instruct udev to reload its rules:sudo udevadm control --reload-rulesYou should now be able to program the board.

Step 5. Connect the Professional MEMS Tool board in DFU mode and run:sudo dfu-util -a 0 -D dfu_path/file.dfu -d 0483:df11where:– dfu_path is the path to the dfu file– file.dfu is the dfu file name

example: sudo dfu-util -a 0 -D Desktop/Professional MEMS ToolV2_REL_4_0.dfu -d0483:df11.

UM2116Firmware upgrade

UM2116 - Rev 8 page 7/41

https://www.st.com/stm32cubeproghttps://www.st.com/stm32cubeproghttps://www.st.com/stm32cubeprog

Step 6. Disconnect and reconnect the board to exit DFU mode and start using the board with the newfirmware.

2.2.3 DFU on Mac OS®The DFU program used for Mac operating systems is dfu-util.

Step 1. Before installing DFU on your Mac OS, you need to install Homebrew. Open a terminal and run:/usr/bin/ruby -e "$(curl -fsSL https://raw.githubusercontent.com/Homebrew/install/master/install)"

Step 2. Install dfu-utils:brew install dfu-utilYou should now be able to program the board

Step 3. Connect the Professional MEMS Tool board in DFU mode, and run:dfu-util -a 0 -D dfu_path/file.dfu -d 0483:0000where:– dfu_path is the path to the dfu file– file.dfu is the dfu file name

example: dfu-util -a 0 -D Desktop/Professional MEMS ToolV2_REL_4_0.dfu -d0483:0000

Step 4. Disconnect and reconnect the board to exit DFU mode and start using the board with the newfirmware.

UM2116Firmware upgrade

UM2116 - Rev 8 page 8/41

3 Supported MEMS adapter boards

Table 1. List of supported MEMS adapter boards

Adapter board Device

STEVAL-MET001V1 LPS22HB

STEVAL-MKI087V1 LIS331DL

STEVAL-MKI089V1 LIS331DLH

STEVAL-MKI092V1 LIS331HH

STEVAL-MKI105V1 LIS3DH

STEVAL-MKI106V1 LSM303DLHC

STEVAL-MKI107V1 L3G4200D

STEVAL-MKI107V2 L3GD20

STEVAL-MKI108V2 9AXISMODULE v2 [LSM303DLHC + L3GD20]

STEVAL-MKI110V1 AIS328DQ

STEVAL-MKI122V1 LSM330DLC

STEVAL-MKI125V1 A3G4250D

STEVAL-MKI134V1 LIS3DSH

STEVAL-MKI135V1 LIS2DH

STEVAL-MKI136V1 L3GD20H

STEVAL-MKI137V1 LIS3MDL

STEVAL-MKI141V1 HTS221

STEVAL-MKI142V1 LPS25H

STEVAL-MKI151V1 LIS2DH12

STEVAL-MKI154V1 LSM9DS0

STEVAL-MKI158V1 AIS3624DQ




STEVAL-MKI163V1 LSM303C

STEVAL-MKI164V1 LIS2HH12

STEVAL-MKI165V1 LPS25HB

STEVAL-MKI166V1 H3LIS100DL

STEVAL-MKI167V1 H3LIS200DL

STEVAL-MKI168V1 IIS2DH

STEVAL-MKI169V1 I3G4250D

STEVAL-MKI170V1 IIS328DQ

STEVAL-MKI172V1 LSM303AGR

STEVAL-MKI173V1 LSM303AH

STEVAL-MKI174V1 LIS2DS12

STEVAL-MKI175V1 LIS2DE12

STEVAL-MKI176V1 LSM6DS3H

UM2116Supported MEMS adapter boards

UM2116 - Rev 8 page 9/41

Adapter board Device

STEVAL-MKI177V1 LPS35HW

STEVAL-MKI178V1 LSM6DSL

STEVAL-MKI178V2 LSM6DSL

STEVAL-MKI179V1 LIS2DW12

STEVAL-MKI180V1 LIS3DHH

STEVAL-MKI181V1 LIS2MDL

STEVAL-MKI182V1 ISM330DLC

STEVAL-MKI183V1 LPS33HW

STEVAL-MKI184V1 ISM303DAC

STEVAL-MKI185V1 IIS2MDC

STEVAL-MKI186V1 IIS3DHHC

STEVAL-MKI188V1 L20G20IS

STEVAL-MKI189V1 LSM6DSM

STEVAL-MKI190V1 LIS2DTW12

STEVAL-MKI191V1 IIS2DLPC

STEVAL-MKI192V1 LPS22HH

STEVAL-MKI193V1 ASM330LHH

STEVAL-MKI194V1 LSM6DSR

STEVAL-MKI195V1 LSM6DSRX

STEVAL-MKI196V1 LSM6DSO

STEVAL-MKI197V1 LSM6DSOX

STEVAL-MKI198V1K STTS751

STEVAL-MKI199V1K STLM20

STEVAL-MKI200V1K STTS22H

STEVAL-MKI201V1K STTS75

STEVAL-MKI202V1K STDS75

STEVAL-MKI203V1K STCN75

STEVAL-MKI204V1K STLM75

STEVAL-MKI205V1 LPS33W

STEVAL-MKI206V1 AIS2DW12

STEVAL-MKI207V1 ISM330DHCX

STEVAL-MKI208V1K IIS3DWB

STEVAL-MKI209V1K IIS2ICLX

STEVAL-MKI210V1K ISM330DHCX

STEVAL-MKI211V1K LIS25BA

STEVAL-MKI213V1 LPS27HHW

STEVAL-MKI214V1 LPS33K

STEVAL-MKI215V1 LSM6DSO32

UM2116Supported MEMS adapter boards

UM2116 - Rev 8 page 10/41

4 Supported commands

The microcontroller mounted on the Professional MEMS Tool board is equipped with dedicated firmware thatallows control of the digital output MEMS sensor, and acquisition of the measured data.The firmware also handles the communication between the board and the PC through the USB bus.

4.1 Getting started

Before using the commands supported by the firmware, the following procedure must be performed:

Step 1. Connect the Professional MEMS Tool to the USB port

Step 2. Launch an application that allows sending commands through the virtual serial port. The remainder ofthis document assumes the use of Microsoft® HyperTerminal program available with the Windows XPoperating system, but you can use any similar tool.

Step 3. Create a new connection, enter a name (e.g. STEVAL-MKI109V3), and click OK.Step 4. In the Connect Using field, select the virtual COM port to which the USB port has been mapped, and

click OK.Step 5. In port settings, set bits per second to 115200, data bits to 8, parity to none, stop bits to

1, and flow control to none; click OKStep 6. In the HyperTerminal application window, select files > properties > settings, then click

ASCII Setup.Step 7. Select Send line ends with line feeds and Echo typed characters locallyStep 8. Click OK to close the ASCII Setup windowStep 9. Click OK button to close the Properties window.

Once this procedure has been completed you can use the commands described in the followingsections by typing them in the “HyperTerminal” window.

4.1.1 Quick startThe basic sequence of commands (based on the LIS3DH accelerometer) to start a data communication sessionand to retrieve X, Y, and Z acceleration data from the demonstration kit is:

Step 1. Connect the Professional MEMS Tool to the USB port

Step 2. Start “Microsoft© HyperTerminal” (or another similar application) and configure it as described inSection 4.1 Getting started

Step 3. Enter the *setdb105v1 command in the HyperTerminal” window, (supposing the LIS3DH adapterboard is used – for other adapters see the relevant datasheets to check the register configuration),enter the command * Zoff to enable the control of the device by the STM32F401VE microcontroller,and *w2047 to switch on the LIS3DH and to set the data rate to 50 Hz

Step 4. Send the *debug command to get the X, Y, and Z data measured by the sensorStep 5. Send *stop to end the continuous acquisition and visualization.

UM2116Supported commands

UM2116 - Rev 8 page 11/41

4.2 Supported commands

The firmware supports a wide range of MEMS adapters; the complete list of supported commands and theirdescriptions are given below. Commands are not case sensitive.

Table 2. List of supported commands

Command Description Returned value(1)

*setdbXXXVY Selects firmware according to the adapterconnected Device name e.g.: LIS3DH

*start Starts continuous data acquisition (see Table 4. Returned values for *start command)

*debug Returns the output data in readable text format

*stop Stops data acquisition

*Zon Forces High impedance state. Turns off VDD andVDDIO power supply.

*Zoff Exits from High impedance state. Turns on VDDand VDDIO power supply

*dev Device name e.g.: LIS3DH

*ver Firmware version e.g.: V1.5.2

*board Returns board name

*rAA Accelerometer register read e.g.: RAAhDDh

*wAADD Accelerometer register write

*grAA Gyroscope register read e.g.: GRAAhDDh

*gwAADD Gyroscope register write

*mrAA Magnetometer register read e.g.: MRAAhDDh

*mwAADD Magnetometer register write

*prAAx Pressure sensor register read e.g.: PRAAhDDh

*pwAADD Pressure sensor register write

*hrAA Humidity sensor register read e.g.: HRAAhDDh

*hwAADD Humidity sensor register write

*trAA Temperature sensorregister read e.g.: TRAAhDDh

*twAADD Temperaturesensor register write

*single It gets a single point data acquisition (see Table 4. Returned values for *start command)

*sindebug It gets a single point data acquisition in readabletext

*list Prints the list of MKIs supported e.g.: 087V1 089V1 092V1 105V1...

*listdev Prints the list of devices supported e.g.: LIS331DL LIS331DLH LIS331HH…

*echoon Activates the write verbose mode e.g.: RAAhDDh

*echooff Deactivates the write verbose mode

*fiforst Accelerometer “Reset mode” enable st XH XL YH YL ZH ZL IR FC FS

*fifomde Accelerometer “FIFO mode” enable st XH XL YH YL ZH ZL IR FC FS

*fifostr Accelerometer “FIFO stream” enable st XH XL YH YL ZH ZL IR FC FS

*fifostf Accelerometer “Stream to FIFO” enable st XH XL YH YL ZH ZL IR FC FS

*fifobtf Accelerometer “Bypass to FIFO” enable st XH XL YH YL ZH ZL IR FC FS

*fifobts Accelerometer “Bypass to stream” enable st XH XL YH YL ZH ZL IR FC FS


UM2116 - Rev 8 page 12/41


*fifodstr Accelerometer “Dynamic stream” enable st XH XL YH YL ZH ZL IR FC FS

*gfiforst Gyroscope “Reset mode” enable st XH XL YH YL ZH ZL IR FC FS

*gfifomde Gyroscope “FIFO mode” enable st XH XL YH YL ZH ZL IR FC FS

*gfifostr Gyroscope “FIFO stream” enable st XH XL YH YL ZH ZL IR FC FS

*gfifostf Gyroscope “Stream to FIFO” enable st XH XL YH YL ZH ZL IR FC FS

*gfifobtf Gyroscope “Bypass to FIFO” enable st XH XL YH YL ZH ZL IR FC FS

*gfifobts Gyroscope “Bypass to stream” enable st XH XL YH YL ZH ZL IR FC FS

*gfifodstr Gyroscope “Dynamic stream” enable st XH XL YH YL ZH ZL IR FC FS

*pfiforst Pressure sensor “Reset mode” enable st XH XL YH YL ZH ZL IR FC FS

*pfifomde Pressure sensor “FIFO mode” enable st XH XL YH YL ZH ZL IR FC FS

*pfifostr Pressure sensor “FIFO stream” enable st XH XL YH YL ZH ZL IR FC FS

*pfifostf Pressure sensor “Stream to FIFO” enable st XH XL YH YL ZH ZL IR FC FS

*pfifobtf Pressure sensor “Bypass to FIFO” enable st XH XL YH YL ZH ZL IR FC FS

*pfifobts Pressure sensor “Bypass to stream” enable st XH XL YH YL ZH ZL IR FC FS

*pfifodstr Pressure sensor “Dynamic stream” enable st XH XL YH YL ZH ZL IR FC FS

*rmAA1NNMultiple read of NN Accelerometer successiveregisters RMAA1hNNhDD1hDD2...DDNNh

*mutli-rAA1AA2 AA3…Accelerometer registers

multiple readMULTI-RAA1hDD1h AA2hDD2h…. AAnDDnh

*grmAA1NNMultiple read of NN Gyroscope successiveregisters GRMAA1hNNhDD1hDD2...DDNNh

*multi-grAA1AA2AA3…

Gyroscope registers

multiple readMULTI-GRAA1hDD1h AA2hDD2h…. AAnDDnh

*mrmAA1NNMultiple read of NN Magnetometer successiveregisters MRMAA1hNNhDD1hDD2...DDNNh

*multi-mrAA1AA2AA3…

Magnetometer registers

multiple readMULTI-MRAA1hDD1h AA2hDD2h…. AAnDDnh

*prmAA1NNMultiple read of NN Pressure sensor successiveregisters PRMAA1hNNhDD1hDD2...DDNNh

*multi-prAA1AA2AA3…

Pressure sensor registers

multiple readMULTI-PRAA1hDD1h AA2hDD2h…. AAnDDnh

*hrmAA1NNMultiple read of NN Humidity sensor successiveregisters HRMAA1hNNhDD1hDD2...DDNNh

*multi-hrAA1AA2AA3…

Humidity sensor registers

multiple readMULTI-HRAA1hDD1h AA2hDD2h…. AAnDDnh

*trmAA1NNMultiple read of NN Temperature sensorsuccessive registers TRMAA1hNNhDD1hDD2...DDNNh

*multi-trAA1AA2AA3…

Temperature sensor registers multiple read MULTI-TRAA1hDD1h AA2hDD2h…. AAnDDnh

*odr [param] Sets ODR speed

1. RP: Reference pressure XLSB.MSB, IR: interrupt byte; FC: FIFO control register; FS: FIFO source register


UM2116 - Rev 8 page 13/41

Table 3. List of supported commands for power supply control and I/V measurement

Command Description Returned value

*power_on Turns on VDD and VDDIO power supply

*power_off Turns off VDD and VDDIO power supply

*setvddaX.Y Sets VDD voltage value “X.Y” Volts. e.g.: 1.8

*setvddioX.Y Sets VDDIO voltage value “X.Y” Volts. e.g.: 1.8

*adc_singleMeasures VDD, VDDIO, IDD, IDDIO and another

values sent in binary formadc:D1D2D3…D20

*get_i [param]Measures IDD, IDDIO with automatic / semiautomatic current rangestoggling and measurement method selection. Output values formatselected by parameters [F / B / A] [S] [C] [L]

e.g. param = A

ida Idd = 152 µA IddIO =0.092 µA

*get_v [param]Measures VDD, VDDIO

Output values format selected by parameters [F/B/A]

e.g. param = A

vda Vdd = 1.807 V VddIO =1.806 V

*ranges_auto Turns on automatic IDD/IDDIO ranges selection (default)

*ranges_man Turns off automatic IDD/IDDIO ranges selection (manual IDD/IDDIOranges selection possible)

*range_ma [param] Selects current range for IDD

*range_mb [param] Selects current range for IDDIO

*adc_run_time [param] Sets time period during which ADC samples the measured currentwaveforms

*adc_uni_stop Stops all measurements

The commands listed in Table 3 work regardless of whether an adapter is physically inserted in the DIL24 socketor not, and also whether the STEVAL-MKIxxxxx of the adapter is selected or not (using the *Setdb command).

4.2.1 *setdbXXXVYThis command selects the part of the firmware able to handle the adapter board sensor connected to the board.For example, *setdb105V1 selects the firmware for the LIS3DH.The D3 LED (yellow) switches on automatically.

4.2.2 *startThis command initiates continuous data acquisition. When sent, the device returns a string of bytes (plus carriagereturn and line feed) like st OUT1 OUT2 OUT3 IR STP BT.The first two bytes are always the ASCII char s and t which correspond to the hexadecimal values {73h 74h}.OUT1, OUT2, and OUT3 contain the values measured at device outputs; if the output data is represented in morethan 8 bits, OUT1, OUT2, and OUT3 are split into high byte (e.g., XH) and low byte (e.g., XL). In case of 24-bitresolution for some sensors, there is also an extra-low byte (e.g., pressure data: PXL PL PH).IR (INT1 INT2) contains the interrupt bytes and BT SW1|SW2 contains the bytes that describe the state of thebuttons integrated on the board.Specifically, bit#0 of the SW1|SW2 data corresponds to the status of the SW1 button on the demonstration kitboard: it is set to 1 when the SW1 is pressed (otherwise 0). Bit#1 has the same behavior but is dedicated to theSW2.STP (STPL STPH) contains the step counter bytes for the internal device step counter value.The string is ended with the carriage return (\r) and line feed (\n) bytes.Before sending the *start command, the device must be out of 3-state (high impedance) and some registersmust be configured according to user needs. Therefore, *start must be preceded by a * zoff and someRegister Write commands.


UM2116 - Rev 8 page 14/41

As data is continuously acquired, LED D1 (green) blinks according to sensor data rate selected.Table 4. Returned values for *start command shows the format of the string returned for each device when a*start command is sent. Similar byte strings are returned for groups of commands related to FIFO, as is shownin Table 5. Digital output accelerometers: supported commands list, Table 6. Digital output gyroscopes: supportedcommands list, Table 7. Digital output magnetometer: supported commands list, Table 8. Digital output pressuresensor: supported commands list, Table 9. Digital output humidity sensor: supported commands list,Table 10. Digital output temperature sensor: supported commands list and Table 11. Analog output temperaturesensor: supported commands list.

Table 4. Returned values for *start command

STEVAL # (Device) Returned value (1)

STEVAL-MKI089V1 (LIS331DLH)

STEVAL-MKI092V1 (LIS331HH)

STEVAL-MKI105V1 (LIS3DH)

STEVAL-MKI110V1 (AIS328DQ)

STEVAL-MKI125V1 (A3G4250D)

STEVAL-MKI134V1 (LIS3DSH)

STEVAL-MKI135V1 (LIS2DH)

STEVAL-MKI136V1 (L3GD20H)

STEVAL-MKI151V1 (LIS2DH12)

STEVAL-MKI158V1 (AIS3624DQ)

STEVAL-MKI164V1 (LIS2HH12)

STEVAL-MKI168V1 (IIS2DH)

STEVAL-MKI170V1 (IIS328DQ)

STEVAL-MKI179V1 (LIS2DW12)

STEVAL-MKI180V1 (LIS3DHH)

STEVAL-MKI186V1 (IIS3DHHC)

STEVAL-MKI191V1 (IIS2DLPC)

STEVAL-MKI206V1 (AIS2DW12)

s t XH XL YH YL ZH ZL int1 int2 sw1|sw2 \r \n

STEVAL-MKI087V1 (LIS331DL)

STEVAL-MKI175V1 (LIS2DE12)s t X Y Z int1 int2 sw1|sw2 \r \n

STEVAL-MKI166V1 (H3LIS100DL)

STEVAL-MKI167V1 (H3LIS200DL)s t X 0 Y 0 Z 0 int1 int2 sw1|sw2 \r \n

STEVAL-MKI208V1K (IIS3DWB) s t XH XL YH YL ZH ZL int1 sw1|sw2 \r \n

STEVAL-MKI174V1 (LIS2DS12)

STEVAL-MKI176V1 (LSM6DS3H)s t XH XL YH YL ZH ZL int1 int2 stpL stpH 0 sw1|sw2 \r \n

STEVAL-MKI137V1 (LIS3MDL)

STEVAL-MKI181V1 (LIS2MDL)

STEVAL-MKI185V1 (IIS2MDC)

s t M_XH M_XL M_YH M_YL M_ZH M_ZL int1 sw1|sw2 \r \n

STEVAL-MKI107V1 (L3G4200D)

STEVAL-MKI107V2 (L3GD20)

STEVAL-MKI169V2 (I3G4250D)

STEVAL-MKI188V1 (L20G20IS)

s t G_XH G_XL G_YH G_YL G_ZH G_ZL

G_int1 G_int2 sw1|sw2 \r \n

STEVAL-MKI122V1 (LSM330DLC)s t A_XH A_XL A_YH A_YL A_ZH A_ZL G_XH G_XL G_YH G_YL G_ZH G_ZL

A_int1 A_int2 G_int1 G_int2 sw1|sw2 \r \n


UM2116 - Rev 8 page 15/41


STEVAL-MKI106V1(LSM303DLHC)s t A_XH A_XL A_YH A_YL A_ZH A_ZL M_XH M_XL M_YH M_YL M_ZH M_ZL

A_int1 A_int2 sw1|sw2 \r \n

STEVAL-MKI108V2 (9AXIS MODULE)

STEVAL-MKI159V1 (LSM9DS1)

s t A_XH A_XL A_YH A_YL A_ZH A_ZL G_XH G_XL G_YH G_YL G_ZH G_ZLM_XH M_XL M_YH M_YL M_ZH M_ZL

A_int1 G_int2 G_int3 0 sw1|sw2 \r \n

STEVAL-MKI154V1 (LSM9DS0)s t A_XH A_XL A_YH A_YL A_ZH A_ZL G_XH G_XL G_YH G_YL G_ZH G_ZLM_XH M_XL M_YH M_YL M_ZH M_ZL

A_int1 A_int2 sw1|sw2 \r \n

STEVAL-MKI159V1 (LSM9DS1)s t A_XH A_XL A_YH A_YL A_ZH A_ZL G_XH G_XL G_YH G_YL G_ZH G_ZLM_XH M_XL M_YH M_YL M_ZH M_ZL

A_int1 A_int2 G_int3 0 sw1|sw2 \r \n



s t A_XH A_XL A_YH A_YL A_ZH A_ZL G_XH G_XL G_YH G_YL G_ZH G_ZL

Int1 Int2 sw1|sw2 \r \n

STEVAL-MKI178V1 (LSM6DSL)

STEVAL-MKI178V2 (LSM6DSL)

STEVAL-MKI182V1 (ISM330DLC)

STEVAL-MKI189V1 (LSM6DSM)


Int1 Int2 StpL StpH 0 sw1|sw2 \r \n

STEVAL-MKI163V1 (LSM303C)s t A_XH A_XL A_YH A_YL A_ZH A_ZL M_XH M_XL M_YH M_YL M_ZH M_ZL

A_int G_int sw1|sw2 \r \n

STEVAL-MKI172V1 (LSM303AGR)s t A_XH A_XL A_YH A_YL A_ZH A_ZL M_XH M_XL M_YH M_YL M_ZH M_ZL

A_int1 Aint2 G_int sw1|sw2 \r \n

STEVAL-MKI173V1 (LSM303AH)

STEVAL-MKI184V1 (ISM303DAC)

s t A_XH A_XL A_YH A_YL A_ZH A_ZL M_XH M_XL M_YH M_YL M_ZH M_ZL

A_int1 A_int2 M_int StpL StpH sw1|sw2 \r \n

STEVAL-MKI142V1 (LPS25H)

STEVAL-MKI165V1 (LPS25HB)

s t PXL PL PH TL TH REF_PXL REF_PL REF_PH

P_int1 sw1|sw2 \r \n

STEVAL-MET001V1 (LPS22HB)

STEVAL-MKI177V1 (LPS35HW)

STEVAL-MKI183V1 (LPS33HW)

STEVAL-MKI192V1 (LPS22HH)

STEVAL-MKI205V1 (LPS33W)

STEVAL-MKI213V1 (LPS27HHW)

STEVAL-MKI214V1 (LPS33K)

s t PXL PL PH TL TH REF_PXL REF_PL REF_PH

P_int1 sw1|sw2 \r \n

STEVAL-MKI141V1 (HTS221) s t HL HH TL TH H_int1 sw1|sw2 \r \n

STEVAL-MKI190 (LIS2DTW12)

STEVAL-MKI193 (ASM300LHH)s t A_XH A_XL A_YH A_YL A_ZH A_ZL Int1 Int2 TL TH sw1|sw2 \r \n

STEVAL-MKI198V1K (STTS751) s t TH TL Int1 sw1|sw2 \r \n

STEVAL-MKI199V1K (STLM20) s t TH TL sw1|sw2 \r \n

STEVAL-MKI200V1K (STTS22H)

STEVAL-MKI201V1K (STTS75)

STEVAL-MKI202V1K (STDS75)

STEVAL-MKI203V1K (STCN75)

STEVAL-MKI204V1K (STLM75)

s t TH TL Int1 sw1|sw2 \r \n

STEVAL-MKI194V1 (LSM6DSR)

STEVAL-MKI196V1 (LSM6DSO)s t A_XH A_XL A_YH A_YL A_ZH A_ZL G_XH G_XL G_YH G_YL G_ZH G_ZL

Int1 Int2 FSMLC_INT FSM1 FSM2 StpL StpH TL TH sw1|sw2 \r \n


UM2116 - Rev 8 page 16/41

STEVAL-MKI215V1 (LSM6DSO32)


STEVAL-MKI211V1K (LIS25BA) s t XH XL YH YL ZH ZL sw1|sw2 \r \n

STEVAL-MKI195V1 (LSM6DSRX)

STEVAL-MKI197V1 (LSM6DSOX)

STEVAL-MKI207V1 (ISM330DHCX)

STEVAL-MKI210V1K (ISM330DHCX)


Int1 Int2 FSMLC_INT FSM1 FSM2 StpL StpH MLC0 MLC1 MLC2 MLC3 MLC4 MLC5

MLC6 MLC7 TL TH sw1|sw2 \r \n

STEVAL-MKI209V1 (IIS2ICLX) s t A_XH A_XL A_YH A_YL Int1 Int2 FSMLC_INT FSM1 FSM2 StpL StpH MLC0MLC1 MLC2 MLC3 MLC4 MLC5 MLC6 MLC7 TL TH sw1|sw2 \r \n

1. XH: X-axis output high byte (same for Y axis, Z axis, G gyroscope, M Magnetometer, P pressure, H humidity, T temperature,Stp step counter). XL: X-axis output low byte (same for Y axis, Z axis, G gyroscope, M Magnetometer, P pressure, Hhumidity, T temperature, Stp step counter) . FSMx: Finite state machine bytes. MLCx:Machine Learning core sourceregisters bytes

4.2.3 *debugThis command starts continuous data acquisition in debug mode. When sent to the board, it returns the outputvalues measured by the device formatted in a readable text format.

4.2.4 *stopThis command interrupts any acquisition session that has been started with either the *start or *debugcommands.

4.2.5 *Zon and *ZoffThese commands put the STM32F401VE microcontroller on the demonstration kit in 3-state (high impedance).They allow the isolation of the sensor from the microprocessor and let the user interact with the sensor in a purelyanalog fashion.When the kit is first turned on, the lines are in 3-state (high impedance) mode and you must send the * Zoffcommand to allow communication between the sensor and the microcontroller.After this command has been executed, LED D2 (Red) is turned on. If the * Zoff command has not beenlaunched, the firmware ignores any other command sent to sensor.

4.2.6 *devThis command retrieves the name of the adapter connected to the demonstration kit; e.g., LIS3DH.

4.2.7 *verThis command returns the version of the firmware loaded in the microprocessor; e.g., V1.5.2.

4.2.8 *rAAThis command reads the contents of the accelerometer registers in the demonstration kit board. The hexadecimalvalue AA written in upper case represents the address of the register to be read.Once the read command is issued, the board returns RAAhDDh, where AA is the address sent by the user and DDis the data present in the register.For example, to read the register at address 0x20, the user issues the command *r20, which would return aresult like R20hC7h.

4.2.8.1 *rmAA1NNThis command allows the contents of multiple accelerometer registers in the demonstration kit board to be read insingle data block. Once this command is issued, the board returns a set of NN values starting withRMAA1hNNhDD1hDD2h… DDNNh where AA1 is the starting address set by user and DD1 is the data present in thisregister and so on for next registers.For example, *rm2006 reads six registers starting from 0x20, which would return a result likeRM20h06h27h00h00h00hA0h0Bh.


UM2116 - Rev 8 page 17/41

4.2.8.2 *multi-rAA1AA2AA3...AANThis command reads multiple accelerometer registers in the demonstration kit board in a single data block. Oncethis command is issued, the board returns set of N values starting RAA1hDD1h… AANhDDNh where AA1 is thestarting address set by user and DD1 is the data present in this register.For example, *multi-r202425292B2D reads six register starting from 0x20, which would return a result likeMULTI-R20h27h24hA0h25h0Bh29hE0h2Bh3Fh2Dh90h.

4.2.9 *wAADDThis command writes the contents of the accelerometer registers in the demonstration kit board. The hexadecimalupper case values AA and DD represent the address of the register and the data to be written, respectively.For example, *w20C7 writes 0xC7 to the register at address 0x20

4.2.10 *grAASection Revision historySection Revision historyThis command allows the contents of the gyroscope registers inthe demonstration kit board to be read. The hexadecimal, upper case AA represents the address of the register tobe read.Once the read command is issued, the board returns GRAAhDDh, where AA is the address sent by the user andDD is the data present in the register.For example, *gr20 reads the register at address 0x20, which would return a result like GR20hC7h.

4.2.10.1 *grmAA1NNThis command allows the contents of multiple gyroscope registers in the demonstration kit board to be read insingle data block. Once this command is issued, the board returns set of NN values starting withGRMAA1hNNhDD1hDD2h… DDNNh where AA1 is the starting address set by user and DD1 is the data present in thisregister and so on.For example, *grm2006 reads six registers starting from 0x20, which would return a result likeGRM20h06h27h00h00h00hA0h0Bh.

4.2.10.2 *multi-grAA1AA2AA3...AANThis command reads multiple gyroscope registers in the demonstration kit board in a single data block. Once thiscommand is issued, the board returns set of N values starting with MULTI-GRAA1hDD1h… AANhDDNh where AA1is the starting address set by user and DD1 is the data present in this register and so on.For example, *multi-gr202425292B2D reads six registers starting from 0x20, which would return a result likeMULTI-GR20h27h24hA0h25h0Bh29hE0h2Bh3Fh2Dh90h.

4.2.11 *gwAADDThis command writes the contents of the gyroscope registers in the demonstration kit board. The hexadecimal,upper case. AA and DD represent the address of the register and the data to be written, respectively.For example, *gw20C7 writes 0xC7 to the register at address 0x20.

4.2.12 *mrAAThis command allows the contents of the magnetometer registers in the demonstration kit board to be read. Thehexadecimal, upper case AA represents the address of the register to be read.Once the read command is issued, the board returns MRAAhDDh, where AA is the address sent by the user andDD is the data present in the register.For example, *mr00 reads the register at address 0x00, which would return a result like MR00h10h.

4.2.12.1 *mrmAA1NNThis command readss the contents of multiple magnetometer registers in the demonstration kit board in a singledata block. Once this command is issued, the board returns set of NN values starting with RMAA1hNNhDD1hDD2h…DDNNh where AA1 is the starting address set by user and DD1 is the data present in this register.For example, *mrm2006 reads six register starting from 0x20, which would return a result likeMRM20h06h27h00h00h00hA0h0Bh.


UM2116 - Rev 8 page 18/41

4.2.12.2 *multi-mrAA1AA2AA3...AANThis command reads multiple magnetometer registers in the demonstration kit board in a single data block. Oncethis command is issued, the board returns set of N values starting with MULTI-MRAA1hDD1h… AANhDDNh, whereAA1 is the starting address set by user and DD1 is the data present in this register, and so on.For example, *multi-mr202425292B2D reads six registers starting from 0x20, which would return a result likeMULTI-MR20h27h24hA0h25h0Bh29hE0h2Bh3Fh2Dh90h.

4.2.13 *mwAADDThis command writes the contents of the magnetometer registers in the demonstration kit board. Hexadecimal,upper case AA and DD represent the address of the register and the data to be written, respectively.For example, *mw0120 writes 0x20 to the register at address 0x01.

4.2.14 *prAAThis command reads the contents of the pressure sensor registers in the demonstration kit board. Thehexadecimal, upper case AA represents the address of the register to be read.Once the read command is issued, the board returns PRAAhDDh, where AA is the address sent by the user andDD is the data present in the register.For example, *pr20 reads the register at address 0x20, which would return a value like PR20h10h.

4.2.14.1 *prmAA1NNThis command reads the contents of multiple pressure sensor registers in the demonstration kit in a single datablock. Once this command is issued, the board returns set of NN values starting with PRMAA1hNNhDD1hDD2h…DDNNh where AA1 is the starting address set by user and DD1 is the data present in this register, and so on…For example, *prm2006 reads six registers starting from 0x20, which would return a value likePRM20h06h27h00h00h00hA0h0Bh.

4.2.14.2 *multi-prAA1AA2AA3...AANThis command reads multiple pressure sensor registers in the demonstration kit board in a single data block.Once this command is issued, the board returns set of N values starting with MULTI-PRAA1hDD1h… AANhDDNhwhere AA1 is the starting address set by user and DD1 is the data present in this register, and so on.For example, *multi-pr202425292B2D reads six registers starting from 0x20, which would return a result likeMULTI-PR20h27h24hA0h25h0Bh29hE0h2Bh3Fh2Dh90h.

4.2.15 *pwAADDThis command writes the contents of the pressure sensor registers in the demonstration kit board. Thehexadecimal, upper case AA and DD represent the address of the register and the data to be written, respectively.For example, *pw20C7 writes 0xC7 to the register at address 0x20.

4.2.16 *hrAAThis command reads the contents of the humidity sensor registers in the demonstration kit board. Thehexadecimal, upper case AA represents the address of the register to be read.Once the read command is issued, the board returns HRAAhDDh, where AA is the address sent by the user andDD is the data present in the register.For example, *hr20 reads the register at address 0x20, which would return a result like HR20h10h.

4.2.16.1 *hrmAA1NNThis command reads the contents of multiple humidity sensor registers in the demonstration kit board in a singledata block. Once this command is issued, the board returns set of NN values starting withHRMAA1hNNhDD1hDD2h… DDNNh where AA1 is the starting address set by user and DD1 is the data present in thisregister, and so on.For example, *hrm2006 reads six registers starting from 0x20, which would return a result likeHRM20h06h27h00h00h00hA0h0Bh.


UM2116 - Rev 8 page 19/41

4.2.16.2 *multi-hrAA1AA2AA3...AANThis command reads multiple humidity sensor registers in the demonstration kit board in a single data block.Once this command is issued, the board returns set of N values starting with MULTI-HRAA1hDD1h… AANhDDNhwhere AA1 is the starting address set by user and DD1 is the data present in this register, and so on.For example, *multi-hr202425292B2D reads six registers starting from 0x20, which would return a result likeMULTI-HR20h27h24hA0h25h0Bh29hE0h2Bh3Fh2Dh90h.

4.2.17 *hwAADDThis command writes the contents of the humidity sensor registers in the demonstration kit board. Thehexadecimal, upper case AA and DD represent the address of the register and the data to be written, respectively.For example *hw20C7 writes 0xC7 to the register at address 0x20.

4.2.18 *trAAThis command reads the contents of the temperature sensor registers in the demonstration kit board. Thehexadecimal, upper case AA represents the address of the register to be read. Once the read command is issued,the board returns TRAAhDDh, where AA is the address sent by the user and DD is the data present in the register.For example, *tr20 reads the register at address 0x20, which would return a result like TR20h10h.

4.2.18.1 *trmAA1NNThis command reads the contents of multiple temperature sensor registers in the demonstration kit board in asingle data block. Once this command is issued, the board returns set of NN values starting withTRMAA1hNNhDD1hDD2h… DDNNh where AA1 is the starting address set by user and DD1 is the data present in thisregister, and so on. For example, *trm2006 reads six registers starting from 0x20, which would return a resultlike TRM20h06h27h00h00h00hA0h0Bh.

4.2.18.2 *multi-trAA1AA2AA3...AANThis command reads multiple temperature sensor registers in the demonstration kit board in a single data block.Once this command is issued, the board returns set of N values starting with MULTI-TRAA1hDD1h… AANhDDNhwhere AA1 is the starting address set by user and DD1 is the data present in this register, and so on. For example,*multi-tr202425292B2D reads six registers starting from 0x20, which would return a result like MULTI-TR20h27h24hA0h25h0Bh29hE0h2Bh3Fh2Dh90h.

4.2.19 *twAADDThis command writes the contents of the temperature sensor registers in the demonstration kit board. Thehexadecimal, upper case AA and DD represent the address of the register and the data to be written, respectively.For example *tw20C7 writes 0xC7 to the register at address 0x20.

4.2.20 *singleThis command may be used to read just one set of data. It returns the read values of one data sample if thesensor is configured properly.

4.2.21 *sindebugThis command returns a single point data acquisition in readable text ASCII format.

4.2.22 *listThe command returns the list of MKI adapters supported by the firmware in ASCII format.

4.2.23 *listdevThis command returns the list of devices supported by the firmware in ASCII format.

4.2.24 *echoonThis command is used to activate the write command verbose mode so that the firmware automatically reads thecontents of a register that has just been written to check if the write was successful.For example, * echoon launched after *w2027 returns R2027.

4.2.25 *echooffThis command stops the write command verbose mode.


UM2116 - Rev 8 page 20/41

4.2.26 *fiforstThis command enables the accelerometer FIFO reset mode. For more details see application note AN3308 onwww.st.com.

4.2.27 *fifomdeThis command enables the accelerometer FIFO mode. For more details see application note AN3308 onwww.st.com.

4.2.28 *fifostrThis command enables the accelerometer FIFO stream mode. For more details see application note AN3308 onwww.st.com.

4.2.29 *fifostfThis command enables the accelerometer Stream-to-FIFO mode. For more details see application note AN3308on www.st.com.

4.2.30 *fifobtfThis command enables the accelerometer Bypass-to-FIFO mode.

4.2.31 *fifobtsThis command enables the accelerometer Bypass-to-Stream mode.

4.2.32 *fifodstrThis command enables the accelerometer Dynamic Stream mode.

4.2.33 *gfiforstThis command enables the gyroscope FIFO reset mode.

4.2.34 *gfifomdeThis command enables the gyroscope FIFO mode.

4.2.35 *gfifostrThis command enables the gyroscope FIFO stream mode.

4.2.36 *gfifostfThis command enables the gyroscope Stream-to-FIFO mode.

4.2.37 *gfifobtfThis command enables the gyroscope Bypass-to-FIFO mode.

4.2.38 *gfifobtsThis command enables the gyroscope Bypass-to-Stream mode.

4.2.39 *gfifodstrThis command enables the gyroscope Dynamic Stream mode.

4.2.40 *pfiforstThis command enables the pressure sensor FIFO reset mode.

4.2.41 *pfifomdeThis command enables the pressure sensor FIFO mode.

4.2.42 *pfifostrThis command enables the pressure sensor FIFO stream mode.

4.2.43 *pfifostfThis command enables the pressure sensor Stream-to-FIFO mode.


UM2116 - Rev 8 page 21/41

4.2.44 *pfifobtfThis command is used to enable the pressure sensor Bypass-to-FIFO mode.

4.2.45 *pfifobtsThis command is used to enable the pressure sensor Bypass-to-Stream mode.

4.2.46 *pfifodstrThis command enables the pressure sensor Dynamic Stream mode.

4.2.47 *setvddaX.Y and *setvddioX.YThese commands set the power supply VDD and VDDIO voltage values of device adapter.For example, *setvdda3.6 sets 3.6V on VDDA. Note that both voltages VDD and VDDIO for modules areindependent. If * setvdda and * setvddio have not been sent before the * power_on command, the setting isthe default voltage defined in the device datasheet selected during the * setdb initialization. Please refer todevice datasheet regarding specified VDD and VDDIO values and their relationship (i.e., which of these can behigher, etc.).As the maximum voltages are defined also by the * setdb command, you cannot set values above these limits.

4.2.48 *power_on and *power_offThese commands are used to switch on and to switch off the VDD and VDDIO power supplies of the deviceadapter together. The proper power-on sequence of both voltages is handled internally by firmware.

4.2.49 *adc_singleThis command is used to get a one-shot set of measured values of VDD and VDDIO voltages; IDD and IDDIOcurrents, etc.

4.2.50 *odr [p1]This command is used to set ODR speed when data acquisition is driven by TIMER (analog sensors).• P1 ODR in mHz: 1 to 2000000

4.2.51 *get_i [p1] [p2] [p3] [p4]This command is used to get average IDD and IDDIO during set/calculated time interval. Current ranges togglingand measurement method selection is done automatically as default setup.• P1 form of output data:

– F or f - floating-point (1 µA base)– B or b - fixed-point (1 nA base)– A or a - ASCII (readable text)

• P2 status bits:– S or s - Two bytes containing information (overflow, underflow, current range index) will be added at the

end of the IDD, IDDIO data• P3 continuous (repetitive) measurement:

– C or c - firmware will send measured values periodically• P4 Long Time Enable:

– L or l firmware will wait for waveform edges or Drdy pulses until it appears or until another *get_i or*adc_uni_stop command interrupts it

4.2.52 *get_v [p1]This command is used to get average VDD and VDDIO VddIO (precise measurement with calibrations).• P1 form of output data:

– F or f - floating-point (1 V base)– B or b - fixed-point (1 mV base)– A or a - ASCII (readable text)


UM2116 - Rev 8 page 22/41

4.2.53 *ranges_auto and *ranges_manThese commands are used to toggle between automatic and manual current ranges selection. The defaultcommand is *ranges_auto.

4.2.54 *range_ma [p1] and *range_mb [p1]These commands are used to select current ranges manually.• *range_ ma … IDD, *range_ mb … IDDIO• P1 current range: 5, 10, 25, 50, 100, 200, 500, 1000, 2500, 5000, 10000, 20000, 50000, 100000• Full scale of the selected range = 300000 / P1 [µA]

4.2.55 *adc_run_time [p1]This command is used to set the time interval during which ADC samples the measured current waveforms.• P1 time in milliseconds: 1 to 50000 (default is 500 ms)

4.2.56 *adc_uni_stopThis command is used to stop all measurements.


UM2116 - Rev 8 page 23/41

4.3 Digital output accelerometers: supported commands

Table 5. Digital output accelerometers: supported commands list


*setdbXXXVY Selects firmware according to the adapter connected

*start Starts continuous data acquisition (See Table 4. Returned values for *start command)



*Zon Forces High impedance state. Turns off VDD andVDDIO power supply

*Zoff Exits from High impedance state. Turns on VDD andVDDIO power supply

*dev Device name e.g.: LIS3DH


*rAA Accelerometer register read e.g.: RAAhDDh

*rmAA1NN Multiple accelerometer registers read e.g.: RMAA1hNNhDD1h…DDNNh

*multi-rAA1 .. AAN Multiple accelerometer registers read e.g.:MULTI-RAA1hDD1h…AANhDDNh

*wAADD Accelerometer register write

*single It gets a single point data acquisition (See Table 4. Returned values for *start command)

*sindebug It gets a single point data acquisition in readable textformat



*echoon Activates the write verbose mode e.g.: RAAhDDh


*fiforst (2) Accelerometer “Reset mode” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*fifomde(2) Accelerometer “FIFO mode” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*fifostr(2) Accelerometer “FIFO stream” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*fifostf(2) Accelerometer “Stream-to-FIFO” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*fifobtf(2) Accelerometer “Bypass-to-FIFO” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*fifobts(2) Accelerometer “Bypass-to-Stream” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*fifodstr(2) Accelerometer “Dynamic Stream” enable st XH XL YH YL ZH ZL IR FC FS \r \n

1. IR: interrupt bytes; FC: FIFO control register; FS: FIFO source register2. Available only for devices with embedded FIFO

UM2116Digital output accelerometers: supported commands

UM2116 - Rev 8 page 24/41

4.4 Digital output gyroscopes: supported commands

The table below lists the commands supported by the devices/demonstration boards including a digital outputgyroscope.

Table 6. Digital output gyroscopes: supported commands list


*setdbXXXVY Selects FW according to the adapter connected




*Zon Forces High impedance state. Turns off VDD andVDDIO power supply

*Zoff Exits from High impedance state. Turns on VDD andVDDIO power supply.

*dev Device name e.g.: L3GD20H


*grAA Gyroscope register read e.g.: GRAAhDDh

*grmAA1NN Multiple gyroscope registers read e.g.: GRMAA1hNNhDD1h…DDNNh

*multi-grAA1 .. AAN Multiple gyroscope registers read e.g.:MULTI-GRAA1hDD1h…AANhDDNh

*gwAADD Gyroscope register write





*echoon Activates the write verbose mode e.g.: GRAAhDDh


*gfiforst (2) Gyroscope “Reset mode” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*gfifomde(2) Gyroscope “FIFO mode” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*gfifostr(2) Gyroscope “FIFO stream” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*gfifostf(2) Gyroscope “Stream to FIFO” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*gfifobtf(2) Gyroscope “Bypass to FIFO” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*gfifobts(2) Gyroscope “Bypass to stream” enable st XH XL YH YL ZH ZL IR FC FS \r \n

*gfifodstr(2) Gyroscope “Dynamic stream” enable st XH XL YH YL ZH ZL IR FC FS \r \n


UM2116Digital output gyroscopes: supported commands

UM2116 - Rev 8 page 25/41

4.5 Digital output magnetometers: supported commands

Table 7. Digital output magnetometer: supported commands list



*start Starts continuous data acquisition (See Table 4. Returned values for *startcommand)



*Zon Forces High impedance state. Turns off VDD and VDDIOpower supply.

*Zoff Exits from High impedance state. Turns on VDD and VDDIOpower supply.

*dev Device name e.g.: LIS2MDL


*mrAA Magnetometer register read e.g.: MRAAhDDh

*mrmAA1NN Multiple magnetometer registers read e.g.: MRMAA1hNNhDD1h…DDNNh

*multi-mrAA1...AAN Multiple magnetometer registers read e.g.:MULTI-MRAA1hDD1h…AANhDDNh

*mwAADD Magnetometer register write

*single It gets a single point data acquisition (See Table 4. Returned values for *startcommand)

*sindebug It gets a single point data acquisition in readable text format


*listdev Prints the list of devices supported e.g.: LIS331DL LIS331DLHLIS331HH…

*echoon Activates the write verbose mode e.g.: MRAAhDDh


1. IR: interrupt bytes; FC: FIFO control register; FS: FIFO source register

UM2116Digital output magnetometers: supported commands

UM2116 - Rev 8 page 26/41

4.6 Digital output pressure sensor: supported commands

Table 8. Digital output pressure sensor: supported commands list


*setdbXXXVY Selects firmware according to the adapterconnected




*Zon Forces High impedance state. Turns off VDD andVDDIO power supply.

*Zoff Exits from High impedance state. Turns on VDD andVDDIO power supply

*dev Device name e.g.: LPS22HH


*prAA Pressure sensor register read e.g.: PRAAhDDh

*prmAA1NN Multiple pressure sensor registers read e.g.: PRMAA1hNNhDD1h…DDNNh

*multi-prAA1 .. AAN Multiple pressure sensor registers read e.g.:MULTI-PRAA1hDD1h…AANhDDNh

*pwAADD Pressure sensor register write





*echoon Activates the write verbose mode e.g.: PRAAhDDh


*pfiforst (2) Pressure sensor “Reset mode” enable st PXL PL PH TL TH IR FC FS \r \n

*pfifomde(2) Pressure sensor “FIFO mode” enable st PXL PL PH TL TH IR FC FS \r \n

*pfifostr(2) Pressure sensor “FIFO stream” enable st PXL PL PH TL TH IR FC FS \r \n

*pfifostf(2) Pressure sensor “Stream to FIFO” enable st PXL PL PH TL TH IR FC FS \r \n

*pfifobtf(2) Pressure sensor “Bypass to FIFO” enable st PXL PL PH TL TH IR FC FS \r \n

*pfifobts(2) Pressure sensor “Bypass to stream” enable st PXL PL PH TL TH IR FC FS \r \n

*pfifodstr(2) Pressure sensor “Dynamic stream” enable st PXL PL PH TL TH IR FC FS \r \n


UM2116Digital output pressure sensor: supported commands

UM2116 - Rev 8 page 27/41

4.7 Digital output humidity sensor: supported commands

The table below lists the commands supported by the devices/demonstration boards including a digital outputhumidity sensor.

Table 9. Digital output humidity sensor: supported commands list






*Zon Forces High impedance state. Turns off VDD and VDDIOpower supply.


*dev Device name e.g.: HTS221


*hrAA Humidity sensor register read e.g.: HRAAhDDh

*hrmAA1NN Multiple humidity sensor registers read e.g.: HRMAA1hNNhDD1h…DDNNh

*multi-hrAA1 .. AAN Multiple humidity sensor registers read e.g.:MULTI-HRAA1hDD1h…AANhDDNh

*hwAADD Humidity sensor register write

*single It gets a single point data acquisition (See Table 4. Returned values for *startcommand)

*sindebug It gets a single point data acquisition in readable text format


*listdev Prints the list of devices supported e.g.: LIS331DL LIS331DLHLIS331HH…

*echoon Activates the write verbose mode e.g.: HRAAhDDh


UM2116Digital output humidity sensor: supported commands

UM2116 - Rev 8 page 28/41

4.8 Digital output temperature sensor: supported commands

The table below lists the commands supported by the devices/evaluation boards including a digital outputtemperature sensor.

Table 10. Digital output temperature sensor: supported commands list


*setdbXXXVY Selects firmware according to theadapter connected

*start Starts continuous data acquisition (See: Table 4. Returned values for *startcommand)

*debug Returns the output data in readabletextformat


*Zon Forces High impedance state. Turns offVDD and VDDIO power supply.

*Zoff Exits from High impedance state. Turnson VDD and VDDIO power supply.

*dev Device name e.g.:STTS22H


*trAA Temperature sensor register read e.g.:TRAAhDDh

*trmAA1NNMultiple temperature sensor registersread e.g.: TRMAA1hNNhDD1h…DDNNh

*multi-trAA1 .. AANMultiple temperature sensor registersread e.g.:MULTI-TRAA1hDD1h…AANhDDNh

*twAADD Temperature sensor register write

*single It gets a single point data acquisition (See: Table 4. Returned values for *startcommand)

*sindebug It gets a single point data acquisition inreadable text format



*echoon Activates the write verbose mode e.g.: TRAAhDDh


UM2116Digital output temperature sensor: supported commands

UM2116 - Rev 8 page 29/41

4.9 Analog output temperature sensor: supported commands

The table below lists the commands supported by the devices/evaluation boards that include an analog outputtemperature sensor.

Table 11. Analog output temperature sensor: supported commands list



*odr [param] Sets ODR speed (parameter: ODR in mHz)


*debug Returns the output data in readable text format e.g.: Temp. = 22.93 [°C]


*Zon Forces High impedance state. Turns off VDD and VDDIO powersupply.


*dev Device name e.g.: STLM20

*ver Firmware version e.g..: V3.7.30

*single Gets a single point data acquisition (SeeTable 4. Returned values for *startcommand)

*sindebug Gets a single point data acquisition in readable text format e.g.: Temp. = 22.93 [°C]

*list Prints the list of STEVAL-MKIxxxxx evaluation boardssupported e.g.: 087V1 089V1 092V1 105V1, etc.

*listdev Prints the list of devices supported e.g.: LIS331DL LIS331DLH LIS331HH, etc.

UM2116Analog output temperature sensor: supported commands

UM2116 - Rev 8 page 30/41

5 Schematic diagrams

Figure 7. STEVAL-MKI109V3 circuit schematic (1 of 8)

USB_D-USB_D+

USB_Disc

Vin

VDD_3.6V

Vext_senseVusb_sense

Professional_MEMS_Tool_v1.0.5_Power

BT_TXBT_RTSBT_RX

BT_CTSBT_RST

VDD_3.6V

MISO_RFMOSI_RFSCK_RFCE_RF

Professional_MEMS_Tool_v1.0.5_Bluetooth

CTR_EN

VD

D_D

UT

VD

DIO

_DU

T

VD

DIO

VDD_3.6V

DIR_GP

CTR_EN_I2C_SDILOCK_1V98

TEST_Adapter_ConnectedTEST_3V6

PWM_TEST

TEST_5TEST_6

DIR_INT3_INT4DIR_DEN_CS_A

Log Signals

Professional_MEMS_Tool_v1.0.5_Adapter

CTR_EN

BT_TXBT_RTSBT_RX

BT_CTSBT_RST

USB_D-USB_D+

USB_Disc

VDD_3.6V

Control Signals A

Control Signals B

ADC_V_REF

Analog Signals A

Analog Signals B

MISO_RF

SCK_RFMOSI_RF

CE_RFDIR_GP

CTR_EN_I2C_SDILOCK_1V98

Vext_senseVusb_sense

TEST_Adapter_ConnectedTEST_3V6PWM_TEST

TEST_5TEST_6

DIR_INT3_INT4DIR_DEN_CS_A

Log Signals

Professional_MEMS_Tool_v1.0.5_MCU

ADC_V_REF

VD

D_D

UT

VD

DIO

_DU

T

VD

DIO

Vin

Control Signals A

Control Signals B

Analog Signals A

Analog Signals B

VDD_3.6V

Professional_MEMS_Tool_v1.0.5_Vdd_control_Idd_meas

STM32F401VET6


Vin

PWM_APWM_B

VDD_3.6V

VDDIO_DUTVDD_DUT

ADC_V_REF

Sense_Hi_B

Sense_Lo_A

Sense_Lo_B

Sense_Hi_ARANGE_100x_ARANGE_100x_B

Professional_MEMS_Tool_v1.0.5_Vdd_control

Sense_Lo_ASense_Hi_A

RANGE_2x_A

FILTER_BSense_Lo_ampl_B

Sense_Lo_B

ADC_I_A_(1)ADC_I_A_(2)

VDDIO

Sense_Lo_ampl_A

4.3V_B

FILTER_A_(1)

Vin

ADC_V_B

FILTER_A_(2)

ADC_V_REF

Sense_Hi_B

ADC_I_B

ADC_V_A

RANGE_20x_ARANGE_50x_A

RANGE_5x_B

RANGE_5x_A

RANGE_20x_B

RANGE_2x_B

4.3V_A

VDD_3.6V

Professional_MEMS_Tool_v1.0.5_Idd_measurement_2CH_lin

4.3V_A

Sense_Lo_ampl_A

ADC_log_I_B

Sense_Lo_ampl_B

4.3V_B

Sense_Hi_B

ADC_log_I_A

Sense_Hi_AADC_V_REF

VDD_3.6V

Professional_MEMS_Tool_v1.0.5_Idd_measurement_2CH_log

R_100x_A

R_20x_AR_5x_A

PWM_A

R_50x_A

R_2x_A

Control Signals A

Control Signals A

RANGE_50x_A

FILTER_A_(2)

RANGE_20x_A

RANGE_100x_APWM_A

R_100x_B

R_20x_BR_5x_B

PWM_B

R_2x_B

Control signals B

Control Signals B

RANGE_20x_B

FILTER_B

RANGE_5x_B

RANGE_100x_BPWM_B

ADC_I_A_(2)

ADC_log_I_AADC_V_A

ADC_I_A_(1)

FILTER_A( 1)FILTER_A (2)

Analog Signals A

ADC_I_A_(2)ADC_V_A

ADC_I_A_(1)

ADC_I_B

ADC_log_I_BADC_V_B

FILTER_B

Analog Signals B

Analog Signals BADC_I_BADC_V_BADC_log_I_B

RANGE_100x_ARANGE_100x_B

PWM_APWM_B

ADC_V_REF

ADC_V_REF

ADC_V_REFADC_log_I_AADC_log_I_B VDDIO

ADC_V_REF

VDDIO_DUTVDD_DUT

Vin

ADC_log_I_AAnalog Signals A

RANGE_2x_B


FILTER_A_(1)

VDD_3.6V

2 x STR2N2VH5 2 x STT7P2UH72 x 2STR2230

6655

7 7

2 x TSV632IQ2T

D

SEL S2

S1

1 x AS21P2TLR

2233

1 1

2 x TSZ122IQ2T

2233

1 1

5 x TSZ122IQ2T

6655

7 7

1 x TSV632IQ2T

TS3431CILT

D

SEL S2

S1

4 x AS21P2TLR

UM2116Schematic diagrams

UM2116 - Rev 8 page 31/41


47uFC22

GND

Dual channel Vdd control

Au = 1.20

100k

R13100k

R12

22nFC8

22nFC10

22nFC9

GND

GNDGND

100k

R31100k

R30

22nFC15

22nFC17

22nFC16

GND

GNDGND

GNDGND

GND

3.6V

470k

R25

470k

R44

6.8RR53

10R

R71

0.1% 0805

GND

5Vin

1kR70

0.1%100kR69

10uFC30

3k3R59

10RR130

10uFC25

GND

100k

R1315Vin

GND

To MEMS

100nFC23

GND

PWM + Filter

VDD_set_A VDD_set_B

47uFC32

GND

6.8RR113

10R

R94

0.1% 0805

5Vin

1kR92

0.1%100kR91

10uFC40

3k3R144

10RR140

10uFC34

GND

100k

R1325Vin

GND

100nFC33

GND

To MEMS

VDD_set_A VDD_set_B

ADC_V_REF

4.7uF

C28

4.7uF

C36

VDD_DUT VDDIO_DUT

CH_A

CH_A

CH_B

CH_B

PWM controlled Power Supply

AS21P2TLR

D 10

SEL 9

S12

S21

U5A

AS21P2TLR

D 5

SEL 4

S17

S26

U5BRef 3.00V Ref 3.00V

20kR19

20kR36

100kR22

100kR43

PDTC115EE,115

3

1

2

T12

PDTC115EE,115

3

1

2

T6

BC857BT,115

3

1

2

T3 BC857BT,115

3

1

2

T8

12

J13

12

J14

5VinVin

FB1

PWM_A PWM_B

AS2

1P2T

LRV

cc3

GN

D8

U5C

VDD_3.6V 3.6V

5Vin

GND

Au = 1.20

RANGE_100x_A

PWM_A PWM_B

RANGE_100x_B

Sense_Hi_A

Sense_Lo_A

Sense_Hi_B

Sense_Lo_B

2233

1 1

TSV632IQ2T

U1A

6655

7 7

TSV632IQ2T

U1B

84

TSV

632I

Q2T

U1C

22

331 1

TSV632IQ2T

U2A

66

557 7

TSV632IQ2T

U2B

84

TSV

632I

Q2T

U2C

100nFC77

100nFC78

22RR157

22RR158

5Vin

GND GND

100nFC79

GND

GND GND

4k7

R175

4k7

R1774k7

R604k7

R176

4k7

R1004k7

R178

100nFC99

100nFC100

3

1

2

2STR2230T4

1

3

4256

STT7P2UH7

T23

1

2

STR2N2VH5

T7

3

1

2

STR2N2VH5

T11

1

3

4256

STT7P2UH7

T10

3

1

2

2STR2230T9


TS3431CILTU10

GND GND

5Vin_1

V1 - Dual Channel Idd measurement - linAu = 1 - 2 - 5 - 10 Differential Amp. Au = 5

Ref 3.00V

GND GNDGND

100k

R80.1%

100k

R23

0.1%

20kR7

0.1%

20k

R18

0.1%

GND

10kR20

GND

Sense_Hi_A

10k

R11

Sense_Lo_A

10k

R24

0.1%

10k

R280.1%

GND

470k

R29

470k

R1GND

GND

ADC_V_REF

Sense_Lo_BVDDIO

To Level Shifters VL

CH_A

CH_B

10uF

C39

GND

5Vin_1

GND

4.3V_A

GND

AS21P2TLR

D10

SEL9

S1 2

S2 1

U8A

AS21P2TLR

D5

SEL4

S1 7

S2 6

U8B

AS2

1P2T

LRV

cc3

GN

D8

U8C

AS2

1P2T

LRV

cc3

GN

D8

U9C

3k6R99

0.1%

5k1R95

0.1%

Ref 3.00V

120k

R97

270k

R96

470RR89

5Vin_1Vin

100pFC12

100pFC7

470nFC6

150pF

C13

GND

GND

AS2

1P2T

LRV

cc3

GN

D8

U13C 1uFC35

GND

10R

R86

22R

R98

22R

R93

10uFC41

10uFC37

4.3V_B 100nF

C38

100nF

C42

4.3V_A

4.3V_A 4.3V_B

4.3V_B4.3V_B

Sense_Hi_A

Sense_Lo_ampl_A

Sense_Lo_AADC_I_A_(1) ADC_V_A

FILTER_A_(1)RANGE_2x_A

RANGE_5x_A

GND

GND

Au = 10 - 20 - 50 - 100 Differential Amp. Au = 10

100k

R30.1%

100k

R56

0.1%

10kR57

GND

Sense_Hi_A

10k

R21

Sense_Lo_A

470k

R61

470k

R62GND

GND

AS21P2TLR

D10

SEL9

S1 2

S2 1

U13A

AS21P2TLR

D5

SEL4

S1 7

S2 6

U13B

100pFC20

100pFC19

150pF

C24

GND

470nFC21

ADC_I_A_(2)

FILTER_A_(2)RANGE_20x_A

RANGE_50x_A

GND

GND

GND

AS2

1P2T

LRV

cc3

GN

D8

U17C

4.3V_A

Au = 1 - 5 - 20 - 100 Differential Amp. Au = 5 - 10

100k

R640.1%

100k

R142

0.1%

20kR63

0.1%

20kR141

0.1%

10kR143

GND

10k

R67

10k

R148

0.1%

10k

R1500.1%

GND

470k

R151

470k

R156GND

GND

AS21P2TLR

D10

SEL9

S1 2

S2 1

U17A

AS21P2TLR

D5

SEL4

S1 7

S2 6

U17B

100pFC64

100pFC27

470nF

C26

150pF

C66

GND

Sense_Hi_B

Sense_Lo_ampl_B

Sense_Lo_BADC_I_B

ADC_V_B

FILTER_BRANGE_5x_B

RANGE_20x_B

GND

GND

Sense_Lo_B

10k

R2

0.1%

10k

R55

0.1%

AS21P2TLR

D10

SEL9

S1 2

S2 1

U9A

AS21P2TLR

D5

SEL4

S1 7

S2 6

U9B

20kR65

0.1%

20kR149

0.1%

RANGE_2x_B

4.3V_B

27k

R27

0.1%

27k

R58

0.1%

3k0R9

0.1%

4k7

R14

0.1%

82kR10

24k

R15

0.1%

3k0

R4

0.1%

2k4

R51

0.1%

300RR48

0.1%

27k

R147

0.1%

3k0

R84

0.1%

300R

R87

0.1%

1k5R85 0.1%

20kR88 0.1%

6k8R116 0.1%

137kR66

4.3V_A4.3V_A

4.3V_B

2233

1 1

TSZ122IQ2T

U3A

6655

7 7

TSZ122IQ2T

U3B

84 TS

Z122

IQ2T

U31C

2233

1 1

TSZ122IQ2T

U15A

6655

7 7

TSZ122IQ2T

U15B

GND

4.3V_A8

4 TSZ1

22IQ

2TU15C

2233

1 1

TSZ122IQ2T

U16A

6655

7 7

TSZ122IQ2T

U16B

GND

84 TS

Z122

IQ2T

U16C

2233

1 1

TSV632IQ2T

U11A

6655

7 7

TSV632IQ2T

U11B

84 TS

V63

2IQ

2T

U11C

100nFC80

22R

R159

GND

5Vin_1

4.3V_A

GND

4.3V_A

100nFC82

GND

470k

R160

GND

2233

1 1

TSZ122IQ2T

U31A

6655

7 7

TSZ122IQ2T

U31B

100kR16

100kR33 GND

4.3V_A

84 TS

Z122

IQ2T

U3C

4.3V_A

100nFC81

GND

4.3V_B

GND

84 TS

Z122

IQ2T

U32C

100kR128

10kR163

GND

10kR164

GND

10kR165

GND

2233

1 1

TSZ122IQ2T

U32A

6655

7 7

TSZ122IQ2T

U32B

GND

100nFC58

GND

100nFC67

GND

100pFC11

100R

R17

100R

R50

100R

R166

GND

100pFC65

1k5

R26

1k5

R101

Sense_Lo_A

3.6V

3.6V

3.6V

3.6V

3.6V

3.6V

100nFC87

GND

GND

1k5

R174

3.6V

GND

GND

22nFC88

22nFC91

100pFC86

VDD_3.6V

RB520S30T1GD10

RB520S30T1GD11

RB520S30T1GD12

RB520S30T1GD13

RB520S30T1GD14

RB520S30T1GD15 4.3V_B

100nFC96

GND

100nFC92

8k2R49

470RR52

0.1%


UM2116 - Rev 8 page 32/41


+Vusb

Power Supply:

GND

GND

GND

3.6V

GND

GND

+Vusb

D-D+

+Vusb

USB D-

USB D+

USB Connection:+Vusb

GND

GNDGND

USB D+

3.6V 3.6V

Vin

USB_D-

USB_D+ USB_Disc

GNDGNDGND

GND

22R

R134

22R

R135

47kR90

1k

R136

10kR133

1k5

R139

470R

R137

100nFC63

100nFC59

100nFC85

1uFC4

LDK220M36RVin1

EN3

2

ByPass/Adj 4Vout 5

GND

U25+Vext Vin

GNDGND

100nFC61

1uFC60

USBLC6-2P6

I/O11

I/O23GND2

I/O2 4VBUS 5

I/O1 6

ESD

U27

VDD_3.6V

D6

DP 3DM 2V+ 1

ID 4US

B

GND 5

0

J5

BC846S6

2

1

T16ABC846S

3

5

4

T16B

1k5R124

1k5R125

GND

GND

GND

BC857BT,115

3

1

2

T22

NTA4153NT1G

3

1

2

T20

NTA4153NT1G

3

1

2

T21

100kR68

GNDGND

BAS16XV2T1G D7

100kR54

100kR119

NO

TA

ssem

bled

Vext_sense

Vusb_sense

10kR167

0RR202

0R

R201

D201

36kR138

NOT Assembled

NOT Assembled12

J4

1

3

4256

STT7P2UH7

T17

3

1

22STR2230

T18

3

1

22STR2230

T19Power Supply:- VDD_3.6V ... Power supply for micro & BT- Vin ... 5V for Idd meas. analog circuits

& VDD_DUT/ VDDIO_DUT

Ext. Power5V

Automatic switchingover from Vusb to Vext

USB Connection:- USB device enumeration signal LED- USB ESD filter


CS_A

INT3

DEN

INT2INT1

SCLSDASDO

CS

VDD_DUT GP

INT4

VDDIO_DUT

GND

DIL24 Device Adapter:

VDDIO

CS_A_uP

INT4

DEN

INT1_uP

SCLSDASDO

GP

INT3_uP

GP_uP

DEN_uP

INT3INT4_uP

INT2_uP

VDDIO

Level Translation:

CS_uP CS

3.6V

3.6V

GP

DENCS_A

INT3INT4

CS

SDOSDASCL

INT2INT1

SDO_xSD_xSC_xCS_x

Logic_signals1

CTR_EN

SDO_uPSDA_uPSCL_uP

VDD_DUTVDDIO_DUT

VDDIO VDDIO

123456789101112

242322212019181716151413

J2

123456789

101112

J1

242322212019181716151413

J3

3.6VVDD_3.6V

VDDIO_DUTVDD_DUTINT1

INT2

SN74AVC4T245RSVR

GND10

Vcc_A3 Vcc_B 2

1B2 141B1 15

1OE 1

1A271A16

1DIR42DIR5

2B2 122B1 13

2A292A18

2OE 16

GND 11

U28

1.2 to 3.6V

SN74AVC4T245RSVR

GND10

Vcc_A3 Vcc_B 2

1B2 141B1 15

1OE 1

1A271A16

1DIR42DIR5

2B2 122B1 13

2A292A18

2OE 16

GND 11

U29

1.2 to 3.6V

NTS0104GU12

GND6

Vcc_A 1Vcc_B11

B29B110

OE 12

A2 3A1 2

A3 4A4 5

B38B47

U30

1.65 to 5.5V

VDDIO3.6V

DIR_GP

4.7uFC72

GND

3.6V

100nFC73

100nFC74

100nFC75

4.7uFC68

GND

100nFC69

100nFC70

100nFC71

VDDIO

CS_A

33kR145

CTR_EN

CTR_EN

3.6V

33kR146

100kR152100kR153

100kR154100kR155

CTR_EN_I2C_SDI

LOCK_1V98

22nFC97

GND

22nFC98

GND

TEST_Adapter_Connected

TEST_3V6

PWM_TEST

TEST_5

TEST_5

TEST_6

TEST_6

DIR_INT3_INT4

DIR_DEN_CS_A

VDDIO3.6V

NTS0104GU12

GND6

Vcc_A 1Vcc_B11

B29B110

OE 12

A2 3A1 2

A3 4A4 5

B38B47

U33

1.65 to 5.5V

CTR_EN_I2C_SDI

CTR_EN_I2C_SDI

CS_x_uP

SDO_x_uPSD_x_uPSC_x_uP

CS_x

SDO_xSD_xSC_x

CS_x

SDO_xSD_xSC_x

100nFC101

100nFC102

TEST_5TEST_6

Log Signals

DIL24 Device Adapter- VDD and VDDIO pin separated


UM2116 - Rev 8 page 33/41


3.6V

GND

Bluetooth Module Connection:

GND

GNDGND

3.6V

GND GND

BT_TX_s

BT_RTS_s

GND

GNDBT_TX

BT_RTS

BT_RX

BT_CTS

BT_RST 12345678

J9

GND

3.6V

GND

SCK_RFMOSI_RFMISO_RF

CE_RF

VDD_3.6V

10nFC3

SN74AVC2T244DQMR

GND5

Vcc_A 1Vcc_B8

B26B17

OE 4A2 3A1 2

U22

1.2 to 3.6V

LDK120PU25R

Vin6

EN4

2

ByPass/Adj 3Vout 1

GND

5

N/C

U19

GND

IRQ_RF / CS_SPI

CS_RF

100nFC2

100nFC1

33kR5

33kR6 12

3J8

2.5V

2.5V


BOOT0

JTMS_SWDIOJTCK_SWCLKJTDI

NTRST

CS_uP

SPI2_SDA

SPI2_SCLSDO_uP

JTDO

SW1

SW2

JNTRST

I2C_SCLI2C_SDA

GP_uP

GND

3.6V

BOOT0BOOT1

Not Mounted

BOOT Mode Selection:

I2C_SCLI2C_SDA

SCL_uPSDA_uP

SPI2_SCLSPI2_SDA

3.6V

I2C and SPI connection:

LED

1

3.6V 3.6V

LED

2

3.6V

LED

3

Signal LEDs:

SW1 SW2

3.6V 3.6V

GND GND

User Switches: Interrupt LED signalization:

3.6V 3.6V

GND

JTMS_SWDIOJTCK_SWCLK

GND

JTDOJTDI

JNTRSTNRST

JTAG/SWO Interface: 3.6V

CTR_EN

BT_TX

BT_RTS

BT_RXBT_CTS

BT_RST

USB_D-USB_D+

USB_Disc

1uFC43

100nFC44

100nFC52

GNDGND

GND

4.7uFC51

100nFC53

100nFC54

100nFC55

100nFC56

100nFC57

GND

3.6V

100nFC49

GND

3.6V

3.6V

ABM8-16.000MHZ-B2-T

13

24

X118pF

C47

18pF

C48GND

GND

GND

10kR120

10kR121

10kR122

10kR123

10kR129

10kR104

10kR105

10kR109

10kR110

10kR111

10kR112

4k7R117

4k7R118

100kR126

100kR127

D1 D2 D3D4 D5

330RR107

470RR108

220RR106 220R

R115330RR114

3

1

2

T143

1

2

T13

1 23 45 67 89 10

J6

BOOT1

100R

R103

FB2

1uFC45

100nFC46

22R

R102

ADC_V_REF

VDD_3.6V

SCK_RF

MOSI_RFMISO_RF

CE_RF

PWM_APWM_B

LED1

LED2LED3

CS_RFIRQ_RF / CS_SPI

INT1_uP

INT2_uP

INT2_uPINT1_uP

DIR_GP

STM32F401VET6

LQFP100

PA3 / ADC3 / USART2_RX / TIM2_CH4 / TIM5_CH4 / TIM9_CH226

VSS 74VDD75

ADC14 / PC4 33ADC15 / PC5 34

PB0 / ADC8 / TIM1_CH2N / TIM3_CH335PB1 / ADC9 / TIM1_CH3N / TIM3_CH436

PB2 / BOOT137

PB10 / SPI2_SCK / I2S2_CK / I2C2_SCL / TIM2_CH347

VCAP148

VSS 10VDD19

PB12 / SPI2_NSS / I2S2_WS / I2C2_SMBA / TIM1_BKIN51PB13 / SPI2_SCK / I2S2_CK / TIM1_CH1N52PB14 / SPI2_MISO / I2S2ext_SD / TIM1_CH2N53PB15 / SPI2_MOSI / I2S2_SD / TIM1_CH3N / RTC_REFIN54

I2S2_MCK / USART6_TX / TIM3_CH1 / SDIO_D6 / PC6 63

USART6_CK / TIM3_CH3 / SDIO_D0 / PC8 65I2S_CKIN / I2C3_SDA / TIM3_CH4 / SDIO_D1 / MCO_2 / PC9 66

PA8 / I2C3_SCL / USART1_CK / TIM1_CH1 / OTG_FS_SOF / MCO_167PA9 / I2C3_SMBA / USART1_TX / TIM1_CH2 / OTG_FS_VBUS68PA10 / USART1_RX / TIM1_CH3 / OTG_FS_ID69PA11 / USART1_CTS / USART6_TX / TIM1_CH4 / OTG_FS_DM70PA12 / USART1_RTS / USART6_RX / TIM1_ETR / OTG_FS_DP71

PA13 / *JTMS-SWDIO*72

VSS 27VDD28

PA14 / *JTCK-SWCLK*76PA15 / *JTDI* / SPI1_NSS / SPI3_NSS / I2S3_WS / TIM2_CH1/ TIM2_ETR77

SPI3_SCK / I2S3_CK / SDIO_D2 / PC10 78I2S3ext_SD / SPI3_MISO / SDIO_D3 / PC11 79

SPI3_MOSI / I2S3_SD / SDIO_CK / PC12 80

PB3 / *JTDO-SWO* / SPI1_SCK / SPI3_SCK / I2S3_CK / I2C2_SDA / TIM2_CH289PB4 / *NJTRST* / SPI1_MISO / SPI3_MISO / I2S3ext_SD / I2C3_SDA / TIM3_CH190PB5 / SPI1_MOSI / SPI3_MOSI / I2S3_SD / I2C1_SMBA / TIM3_CH291PB6 / I2C1_SCL / USART1_TX / TIM4_CH192PB7 / I2C1_SDA / USART1_RX / TIM4_CH293

Vpp / BOOT094

PB8 / I2C1_SCL / TIM4_CH3 / TIM10_CH1 SDIO_D495PB9 / SPI2_NSS / I2S2_WS / I2C1_SDA / TIM4_CH4 / TIM11_CH1 / SDIO_D596

VSS 49VDD50

VBAT6

RTC_TAMP1 / RTC_OUT / RTC_TS / PC13 7OSC32_IN / PC14 8

OSC32_OUT / PC15 9

PH0 / OSC_IN12PH1 / OSC_OUT13

NRST14

ADC10 / PC0 15ADC11 / PC1 16

ADC12 / SPI2_MISO / I2S2ext_SD / PC2 17ADC13 / SPI2_MOSI / I2S2_SD / PC3 18

VDDA22

PA0 / ADC0 / USART2_CTS / TIM2_CH1 / TIM2_ETR / TIM5_CH1 / WKUP23PA1 / ADC1 / USART2_RTS / TIM2_CH2 / TIM5_CH224PA2 / ADC2 / USART2_TX / TIM2_CH3 / TIM5_CH3 / TIM9_CH125

PA4 / ADC4 / SPI1_NSS / SPI3_NSS / I2S3_WS / USART2_CK29PA5 / ADC5 / SPI1_SCK / TIM2_CH1 / TIM2_ETR30PA6 / ADC6 / SPI1_MISO / TIM1_BKIN / TIM3_CH131PA7 / ADC7 / SPI1_MOSI / TIM1_CH1N / TIM3_CH232

SPI4_SCK / TRACECLK / PE2 1TRACED0 / PE3 2

SPI4_NSS / TRACED1 / PE4 3SPI4_MISO / TIM9_CH1 / TRACED2 / PE5 4SPI4_MOSI / TIM9_CH2 / TRACED3 / PE6 5

VSS 99VDD100

STM32F401VET6VDD11

VSSA/VREF-20VREF+21

TIM1_ETR / PE7 38TIM1_CH1N / PE8 39

TIM1_CH1 / PE9 40TIM1_CH2N / PE10 41

SPI4_NSS / TIM1_CH2 / PE11 42SPI4_SCK / TIM1_CH3N / PE12 43SPI4_MISO / TIM1_CH3 / PE13 44SPI4_MOSI / TIM1_CH4 / PE14 45

TIM1_BKIN / PE15 46

PD8 55PD9 56

PD10 57PD11 58

TIM4_CH1 / PD12 59TIM4_CH2 / PD13 60TIM4_CH3 / PD14 61TIM4_CH4 / PD15 62

I2S3_MCK / USART6_RX / TIM3_CH2 / SDIO_D7 / PC7 64

VCAP273

PD0 81PD1 82

TIM3_ETR / SDIO_CMD / PD2 83SPI2_SCK / I2S2_CK / USART2_CTS / PD3 84

USART2_RTS / PD4 85USART2_TX / PD5 86

SPI3_MOSI / I2S3_SD / USART2_RX / PD6 87USART2_CK / PD7 88

TIM4_ETR / PE0 97PE1 98

U24

12

J7

12

BT3

12

BT2

12

BT1

ADC_I_A_(2)ADC_V_A

ADC_I_A_(1)

ADC_log_I_A

ADC_I_B

ADC_V_BADC_log_I_B

RANGE_20x_BRANGE_5x_B

RANGE_2x_B

RANGE_100x_B


RANGE_100x_A


CS_uP

SDO_uPSDA_uPSCL_uP

INT1_uPINT2_uP

GP_uPDEN_uPCS_A_uP

INT3_uPINT4_uP

CS_A_uPDEN_uPCS_A_uP

INT3_uPINT4_uP

2.2uFC76

GND

2.2uFC50

N/A in BGA100

CTR_EN_I2C_SDI

100kR1610.1%

LOCK_1V981k

R162 100nFC84

GND

I2C3_SDA

I2C3_SDA

I2C3_SCL

I2C3_SCL

R_100x_A

R_20x_AR_5x_A

PWM_A

R_50x_A

R_2x_A

Control Signals A

Control Signals A

RANGE_50x_A

FILTER_A_(2)

RANGE_20x_A

RANGE_100x_APWM_A

R_100x_B

R_20x_BR_5x_B

PWM_B

R_2x_B

Control signals B

Control Signals B

RANGE_20x_B

FILTER_B

RANGE_5x_B

RANGE_100x_BPWM_B

ADC_I_A_(2)

ADC_log_I_AADC_V_A

ADC_I_A_(1)

FILTER_A( 1)FILTER_A (2)

Analog Signals A

ADC_I_A_(2)ADC_V_A

ADC_I_A_(1)

ADC_I_B

ADC_log_I_BADC_V_B

FILTER_B

Analog Signals B

Analog Signals BADC_I_BADC_V_BADC_log_I_B

ADC_log_I_AAnalog Signals A

RANGE_2x_B


FILTER_A_(1)

FILTER_A_(1)FILTER_A_(2)

FILTER_B

Vext_sense

Vusb_sense

100kR173

100kR171

100kR170

100kR172

GND

22nFC93

GND

22nFC94

Vext_sens/2Vext_sens/2

Vusb_sens/2

Vusb_sens/2

12

J10GND

12

J12GND

Production Test Start GPI

12

J11

Production Tester

GPI

Cal

GPICal3.6V

TEST_Adapter_Connected

TEST_3V6

PWM_TEST

TEST_5

TEST_6

I2C3_SCL

DIR_DEN_CS_A

DIR_INT3_INT4

10k

R179

10k

R180

SW2

GPDENCS_A

INT3INT4

CS

SDOSDASCL

INT2INT1

SDO_xSD_xSC_xCS_x

Logic_signals1

CS_x_uP

SDO_x_uPSD_x_uPSC_x_uP

CS_x_uP

SDO_x_uPSD_x_uP

SC_x_uP

Log Signals

Interconnection Check

BOOT Mode Selection:- Default boot from FLASH (BOOT0 low, BOOT1 low)


UM2116 - Rev 8 page 34/41

Revision history

Table 12. Document revision history

Date Version Changes

05-Oct-2016 1 Initial release.

26-Feb-2018 2 Updated List of supported MEMS adapter boards, List of supported commands and Returned valuesfor *start command

27-Jul-2018 3

Updated List of supported MEMS adapter boards, List of supported commands and Returned valuesfor *start command

Changed all descriptions for *Zon to "Forces High impedance state" (was Forces 3-state) and *Zoff to"Exits from High impedance state" (was Exits from 3-state)

Minor text changes

23-Jan-2019 4Updated Table 1. List of supported MEMS adapter boards and Table 3. Returned values for *startcommand.

Added Section 4.8 Digital output temperature sensor: supported commands.

02-Jul-2019 5 Updated Table 1. List of supported MEMS adapter boards and Table 3. Returned values for *startcommand.

07-Oct-2019 6Updated Section 2 Professional MEMS Tool board installation, Table 1. List of supported MEMSadapter boards and Table 3. Returned values for *start command.

Added Section 2.2.1 Firmware upgrade on Windows.

03-Mar-2020 7 Updated Table 1. List of supported MEMS adapter boards and Table 3. Returned values for *startcommand.

15-Jul-2020 8

Updated Section 2.2.3 DFU on Mac OS®, Section 3 Supported MEMS adapter boards,Section 4.2 Supported commands, Section 4.2.2 *start, Section 4.3 Digital output accelerometers:supported commands, Section 4.4 Digital output gyroscopes: supported commands,Section 4.5 Digital output magnetometers: supported commands, Section 4.6 Digital outputpressure sensor: supported commands, Section 4.7 Digital output humidity sensor: supportedcommands and Section 4.8 Digital output temperature sensor: supported commands.

Added Section 4.2.21 *sindebug, Section 4.2.50 *odr [p1], Section 4.2.51 *get_i [p1] [p2] [p3] [p4],Section 4.2.52 *get_v [p1], Section 4.2.53 *ranges_auto and *ranges_man,Section 4.2.54 *range_ma [p1] and *range_mb [p1], Section 4.2.55 *adc_run_time [p1],Section 4.2.56 *adc_uni_stop and Section 4.9 Analog output temperature sensor: supportedcommands.

UM2116

UM2116 - Rev 8 page 35/41

Contents

1 Demonstration kit description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2

2 Professional MEMS Tool board installation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6

2.1 Hardware installation (Windows® platforms before Windows 10). . . . . . . . . . . . . . . . . . . . . . . 6

2.2 Firmware upgrade . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

2.2.1 Firmware upgrade on Windows. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

2.2.2 DFU on Linux® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

2.2.3 DFU on Mac OS® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

3 Supported MEMS adapter boards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9

4 Supported commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11

4.1 Getting started . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

4.1.1 Quick start. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

4.2 Supported commands. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Documents

User manual - STMicroelectronics...User manual UM2116 - Rev 8 - July 2020 For further information contact your local STMicroelectronics sales office. 1 Demonstration kit description