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This article provides explanations on how the STM32U0 battery less demo works and describes step-by-step how to reproduce it.
1. Presentation of the demo
1.1. Purpose
The goal of this demo is to illustrate the STM32U0 best-in class ultra-low power capabilities. It is running without battery thanks to Dracula technologies inkjet Printed Organic Photovoltaic module, which harvests energy for the STM32U0 MCU. This is a luxmeter and thermometer demo with data being displayed on an LCD segment display, and the possibility to send data thanks to a radiofrequency module.
1.2. Configurations
This demo can be configured in two different versions.
- The first one is referred as the Data logger only configuration. It consists of one STM32U083C-DK Discovery kit powered by one Layer photovoltaic module. Every second, measured temperature or luminosity is displayed on the LCD segment display. By pressing the joystick blue hat of the discovery kit, the user can change which data is being displayed.
- The second one is referred as the Data logger & RF configuration. It consists of two modules, the Data logger & Transmitter module, and the Receiver & Display module.
- The first one is based on the first configuration of the demo, on top of which the X-Nucleo-S2868A2, an RF expansion board. In addition to measuring temperature and luminosity, and displaying one of the two measures on the LDC segment display, it sends each second through the RF module the 2 measures.
- The second one is a module which receives the data and displays it on an LCD screen. It is made of one Nucleo-U083RC and 2 expansion kits, the X-Nucleo-S2868A2 to receive the data, and the X-Nucleo-GFX01M2 with the LCD screen. The 2 measures received are displayed in real time on a graph chart on the LCD screen.
2. How the demo works
2.1. Schematics
The figure below shows schematic of Data logger only configuration on the left, and of Data logger & Transmission configuration on the right.
2.2. Demo principle
The following flowchart and graph describe the principle of the data logger module.
When voltage is first reaching POR voltage (2), only minimal instructions are done before entering stop 2 mode, to consume as little energy as possible. Hence, only PVD is set to level 6 to wake up the STM32U0 when voltage will reach 3.0V (3). This is the critical part of the initialization.
Once voltage reaches 3.0V for the first time (4), initialization of peripheral can start (5). GPIOs, LCD, ADC, communication with the temperature sensor, and, if present, communication with the RF module are initialized. RTC is also configured to wake-up the MCU every second. Then, the MCU enters stop 2 mode until wake up from RTC (6).
After waking up, it first checked that the capacitor is charged enough by checking voltage is over 2V (7). If yes, the measurement phase is entered (8). Temperature is sent by STT22H temperature sensor included in the discovery kit. Light is measured by measuring voltage provided by the panel as explained in part Light measurement. If RF module is present, measured data is sent with this module. Last step is to enter stop 2 again to retrieve energy (9).
2.3. Light measurement
Image below illustrates the flow of current outside of the light measurement phase. PA0 is in open drain configuration so current flows to the capacitor and the STM32U0.
To measure the light, the current through resistor R1 is deduced from the measuring of the voltage provided by the photovoltaic module.
Following formula is then used to deduce luminosity from measured ADC voltage.
To measure the voltage provided by the photovoltaic module, PA0 is configured in output pull-down mode. The diode prevents the current of the capacitor from flowing to the ADC. Figure below illustrates the flow of current during light measurement.
3. How to reproduce
3.1. Bill of material
Data logger & Transmission module
- STM32U083C-DK Discovery kit
- Layer® inkjet Printed Organic photovoltaic product from Dracula Technologies
- 1x diode
- 1x 100µF capacitor
- 1x 2.2kohm resistor
- X-NUCLEO-S2868A2
- 1x 300kohm resistor
Receiver & Display module
3.2. Reproduction of Data logger & Transmission module
Image below shows the connections to do on bottom side of STM32U083-DK.
- 1. Connect PV- to battery–
- 2. Connect PV+ to CN7-38 (PC1)
- 3. Add a diode between CN7-38 (PC1) and battery+
Image below shows the modifications to do on front side of STM32U083-DK and X-Nucleo-S2868A2.
- 4. Add 100µF capacitor
- 5. Add 2.2kΩ resistor between A4 (PC1) and A0 (PA0)
- 6. Add >100kΩ pull-up resistor between VREF (CN5-3) and D7 (CN9-8)
- 7. Remove JP1
Image below shows the modifications to do on bottom side of X-Nucleo-S2868A21.
- 8. Cut CN9-9 and CN9-10
- 9. Connect CN5-8 connected to JP1-1
- 10. Remove R12
3.3. Reproduction of Receiver & Display module
Image below shows modifications to do on S2868A2.
The following solder bridges are to be opened.
- A1. R10 - Disconnect SDN from D7.
- A2. R11 - Disconnect SPI SCLK from D3.
- A3. R12 - Disconnect GPIO0 from A0.
- A4. R13 - Disconnect CSN from A1.
- A5. R14 - Disconnect GPIO1 from A2.
- A6. R15 - Disconnect GPIO2 from A3.
- A7. R16 - Disconnect GPIO3 from A5.
The following solder bridges are to be closed.
- B1. R6 - Connect SPI SCLK to D13.
- B2. R9 - Connect CSN to D10.
- B3. R18 - Connect GPIO0 to A4.
- B4. CN9-3 on R19 (or R10) - Connect SDN to D2. [1]
Image below shows the connections and the modification to be done on Nucleo-U08RC:
- C1. Cut CN7-36 (conflict on this pin between the 2 extension kits).
- C2. Plug 2 SSQ-119-03-T-D 19x2 connectors on Nucleo-connectors.
- C3. Plug S2868A2 on Arduino-connectors.
- C4. Plug GFX01M2 on SSQ-119-03-T-D connectors.
3.4. Option bytes configuration
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3.5. Software
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4. External links
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- ↑ D6 and D7 connectors are used by the display module, so neither of them can be used for SDN pin.