Apply motors configuration without reboot

2026-06-28 05:56:44 +00:00 · 2026-01-27 09:56:39 +03:00
51 changed files with 172 additions and 616 deletions
@@ -23,8 +23,6 @@ jobs:
      with:
        name: firmware-binary
        path: flix/build
    - name: Build firmware for ESP32-C3
      run: make BOARD=esp32:esp32:esp32c3
    - name: Build firmware for ESP32-S3
      run: make BOARD=esp32:esp32:esp32s3
    - name: Check c_cpp_properties.json
@@ -1,5 +1,6 @@
 BOARD = esp32:esp32:d1_mini32
-PORT := $(strip $(wildcard /dev/serial/by-id/usb-Silicon_Labs_CP21* /dev/serial/by-id/usb-1a86_USB_Single_Serial_* /dev/cu.usbserial-* /dev/cu.usbmodem*))
+PORT := $(wildcard /dev/serial/by-id/usb-Silicon_Labs_CP21* /dev/serial/by-id/usb-1a86_USB_Single_Serial_* /dev/cu.usbserial-*)
 PORT := $(strip $(PORT))
 build: .dependencies
 	arduino-cli compile --fqbn $(BOARD) flix
@@ -18,10 +19,6 @@ dependencies .dependencies:
 	arduino-cli lib install "MAVLink"@2.0.25
 	touch .dependencies
 upload_proxy: .dependencies
 	arduino-cli compile --fqbn $(BOARD) tools/espnow-proxy
 	arduino-cli upload --fqbn $(BOARD) -p "$(PORT)" tools/espnow-proxy
 gazebo/build cmake: gazebo/CMakeLists.txt
 	mkdir -p gazebo/build
 	cd gazebo/build && cmake ..
@@ -21,8 +21,8 @@
 * Dedicated for education and research.
 * Made from general-purpose components.
 * Simple and clean source code in Arduino (<2k lines firmware).
-* Communication using MAVLink protocol over Wi-Fi or ESP-NOW.
+* Connectivity using Wi-Fi and MAVLink protocol.
-* Control with USB gamepad, remote control or smartphone.
+* Control using USB gamepad, remote control or smartphone.
 * Wireless command line interface and analyzing.
 * Precise simulation with Gazebo.
 * Python library for scripting and automatic flights.
@@ -53,7 +53,7 @@ The simulator is implemented using Gazebo and runs the original Arduino code:
 <img src="docs/img/simulator1.png" width=500 alt="Flix simulator">
-## Documentation articles
+## Documentation
 1. [Assembly instructions](docs/assembly.md).
 2. [Usage: build, setup and flight](docs/usage.md).
@@ -71,14 +71,14 @@ Additional articles:
 |Type|Part|Image|Quantity|
 |-|-|:-:|:-:|
-|Microcontroller board|ESP32 Mini.<br>ESP32-S3/ESP32-C3 boards are also supported.|<img src="docs/img/esp32.jpg" width=100>|1|
+|Microcontroller board|ESP32 Mini|<img src="docs/img/esp32.jpg" width=100>|1|
-|IMU (and barometer¹) board|GY‑91, MPU-9265 (or other MPU‑9250/MPU‑6500 board)<br>ICM20948V2 (ICM‑20948)<br>GY-521 (MPU-6050)|<img src="docs/img/gy-91.jpg" width=90 align=center><br><img src="docs/img/icm-20948.jpg" width=100><br><img src="docs/img/gy-521.jpg" width=100>|1|
+|IMU (and barometer¹) board|GY‑91, MPU-9265 (or other MPU‑9250/MPU‑6500 board)<br>ICM20948V2 (ICM‑20948)³<br>GY-521 (MPU-6050)³⁻¹|<img src="docs/img/gy-91.jpg" width=90 align=center><br><img src="docs/img/icm-20948.jpg" width=100><br><img src="docs/img/gy-521.jpg" width=100>|1|
 |Boost converter (optional, for more stable power supply)|5V output|<img src="docs/img/buck-boost.jpg" width=100>|1|
 |Motor|8520 3.7V brushed motor.<br>Motor with exact 3.7V voltage is needed, not ranged working voltage (3.7V — 6V).<br>Make sure the motor shaft diameter and propeller hole diameter match!|<img src="docs/img/motor.jpeg" width=100>|4|
-|Propeller|55 mm or 65 mm|<img src="docs/img/prop.jpg" width=100>|4|
+|Propeller|55 mm (alternatively 65 mm)|<img src="docs/img/prop.jpg" width=100>|4|
 |MOSFET (transistor)|100N03A or [analog](https://t.me/opensourcequadcopter/33)|<img src="docs/img/100n03a.jpg" width=100>|4|
-|Pull-down resistor<br>Voltage measurement resistor|10 kΩ|<img src="docs/img/resistor10k.jpg" width=100>|6|
+|Pull-down resistor|10 kΩ|<img src="docs/img/resistor10k.jpg" width=100>|4|
-|3.7V Li-Po battery|LW 952540 (or any compatible by the size).<br>Make sure the battery has enough discharge rate — 25C or more!|<img src="docs/img/battery.jpg" width=100>|1|
+|3.7V Li-Po battery|LW 952540 (or any compatible by the size)|<img src="docs/img/battery.jpg" width=100>|1|
 |Battery connector cable|MX2.0 2P female|<img src="docs/img/mx.png" width=100>|1|
 |Li-Po Battery charger|Any|<img src="docs/img/charger.jpg" width=100>|1|
 |Screws for IMU board mounting|M3x5|<img src="docs/img/screw-m3.jpg" width=100>|2|
@@ -152,16 +152,14 @@ You can see a user-contributed [variant of complete circuit diagram](https://mir
  |-|-|
  |GND|GND|
  |VIN|VCC (or 3.3V depending on the receiver)|
-  |Signal (TX)|GPIO4|
+  |Signal (TX)|GPIO4¹|
-* Optionally connect the battery voltage divider for voltage monitoring to any ADC1 pin (e. g. *GPIO32* on ESP32, *GPIO3* on ESP32-S3).
+*¹ — UART2 RX pin was [changed](https://docs.espressif.com/projects/arduino-esp32/en/latest/migration_guides/2.x_to_3.0.html#id14) to GPIO4 in Arduino ESP32 core 3.0.*
  ESP32 and ESP32-S3 [can measure](https://docs.espressif.com/projects/arduino-esp32/en/latest/api/adc.html#analogsetattenuation) up to 3.1 V and ESP32-S3/ESP32-C3 can measure up to 2.5 V, so choose the voltage divider resistors accordingly.
 ## Resources
 * Telegram channel on developing the drone and the flight controller (in Russian): https://t.me/opensourcequadcopter.
-* Official Telegram chat: https://t.me/opensourcequadcopterchat (English / Russian).
+* Official Telegram chat: https://t.me/opensourcequadcopterchat.
 * Detailed article on Habr.com about the development of the drone (in Russian): https://habr.com/ru/articles/814127/.
 ## Disclaimer
@@ -28,8 +28,6 @@ Soldered components ([schematics variant](https://miro.com/app/board/uXjVN-dTjoo
 <img src="img/assembly/7.jpg" width=600>
 See an alternative assembly process photos here: https://drive.google.com/drive/folders/1FG5BH9RCzdf1XmJcC70PymiRMXcz6Fx7?usp=sharing.
 ## Motor directions
 > [!WARNING]
@@ -67,35 +67,6 @@ In order to add a console command, modify the `doCommand()` function in `cli.ino
 >
 > For on-the-ground commands, use `pause()` function, instead of `delay()`. This function allows to pause in a way that MAVLink connection will continue working.
 ### Parameter subsystem
 Parameters subsystem (`parameters.ino`) uses standard [Preferences.h](https://docs.espressif.com/projects/arduino-esp32/en/latest/tutorials/preferences.html) ESP32 library to store parameters in non-volatile memory. Each parameter is a regular global variable, which is registered in the `parameters` array.
 To add a new parameter:
 1. Define a global variable for the parameter, two types are supported: `float` and `int`.
 2. Add an entry to the `parameters` array, with the parameter name, a pointer to the variable, and optionally a callback function to call when the parameter is changed.
 3. Everything else will be handled automatically.
 See examples of adding new parameters in commits: [c434107](https://github.com/okalachev/flix/commit/c434107), [a687303](https://github.com/okalachev/flix/commit/a687303).
 ## Adding a subsystem
 To add a new subsystem:
 1. Create a new `*.ino` file for your subsystem.
 2. Define setup and loop functions for the subsystem, for example `setupMySubsystem()` and `loopMySubsystem()`.
 3. Use `Rate` class if you need to limit the loop frequency, for example:
    ```cpp
    Rate mySubsystemRate(100); // 100 Hz
    void loopMySubsystem() {
    	if (!mySubsystemRate) return;
    	// Do something...
    }
 4. Add setup and loop calls in to `setup()` and `loop()` functions in `flix.ino`.
 ## Building the firmware
 See build instructions in [usage.md](usage.md).
@@ -12,25 +12,20 @@ Do the following:
 Do the following:
-* **Check the battery voltage**. Use a multimeter to measure the battery voltage. The fully charged battery should have about 4.2V.
+* **Check the battery voltage**. Use a multimeter to measure the battery voltage. It should be in range of 3.7-4.2 V.
-* **Check the battery you use has enough discharge current**. The battery should be able to provide 15A of current. So the C-rating for a 1000 mAh battery should be at least 15C (higher is better).
+* **Check if there are some startup errors**. Connect the ESP32 to the computer and check the Serial Monitor output. Use the Reset button to make sure you see the whole ESP32 startup output.
 * **Check if there are some startup errors**. Connect the ESP32 to the computer and check the Serial Monitor output. Use the Reset button or `reboot` command to see the whole startup output.
 * **Check the baudrate is correct**. If you see garbage characters in the Serial Monitor, make sure the baudrate is set to 115200.
 * **Make sure correct IMU model is chosen**. If using ICM-20948/MPU-6050 board, change `MPU9250` to `ICM20948`/`MPU6050` in the `imu.ino` file.
 * **Check if the console is working**. Perform `help` command in Serial Monitor. You should see the list of available commands. You can also access the console using QGroundControl *(Vehicle Setup* ⇒ *Analyze Tools* ⇒ *MAVLink Console)*.
 * **Configure QGroundControl correctly before connecting to the drone** if you use it to control the drone. Go to the settings and enable *Virtual Joystick*. *Auto-Center Throttle* setting **should be disabled**.
 * **If QGroundControl doesn't connect**, you might need to disable the firewall and/or VPN on your computer.
 * **Make sure correct IMU model is chosen**. If using ICM-20948/MPU-6050 board, change `MPU9250` to `ICM20948`/`MPU6050` in the `imu.ino` file.
 * **Check the IMU is working**. Perform `imu` command and check its output:
  * The `status` field should be `OK`.
  * The `rate` field should be about 1000 (Hz).
  * The `accel` and `gyro` fields should change as you move the drone.
 * **Check the IMU orientation is set correctly**. If the attitude estimation is rotated, set the correct IMU orientation as described in the [tutorial](usage.md#define-imu-orientation).
 * **Calibrate the accelerometer.** if is wasn't done before. Type `ca` command in Serial Monitor and follow the instructions.
-* **Check the attitude estimation**. Connect to the drone using QGroundControl. Rotate the drone in different orientations and check if the attitude estimation is shown exactly as on the video below:
+* **Check the attitude estimation**. Connect to the drone using QGroundControl. Rotate the drone in different orientations and check if the attitude estimation shown in QGroundControl is correct.
-
+* **Check the IMU orientation is set correctly**. If the attitude estimation is rotated, set the correct IMU orientation as described in the [tutorial](usage.md#define-imu-orientation).
  <a href="https://youtu.be/yVRN23-GISU"><img width=200 src="https://i3.ytimg.com/vi/yVRN23-GISU/maxresdefault.jpg"></a>
 * **Check the IMU output**. Connect to the drone using QGroundControl on your computer. Go to the *Analyze* tab, *MAVLINK Inspector*. Plot the data from the `SCALED_IMU` message. The gyroscope and accelerometer data should change according to the drone movement.
 * **Check the motors type**. Motors with exact 3.7V voltage are needed, not ranged working voltage (3.7V — 6V).
 * **Check the motors**. Perform the following commands using Serial Monitor:
  * `mfr` — should rotate front right motor (counter-clockwise).
@@ -38,10 +33,7 @@ Do the following:
  * `mrl` — should rotate rear left motor (counter-clockwise).
  * `mrr` — should rotate rear right motor (clockwise).
 * **Check the propeller directions are correct**. Make sure your propeller types (A or B) are installed as on the picture:
  <img src="img/user/peter_ukhov-2/1.jpg" width="200">
-
+* **Check the remote control**. Using `rc` command, check the control values reflect your sticks movement. All the controls should change between -1 and 1, and throttle between 0 and 1.
-* **If using an SBUS receiver**:
+* If using SBUS receiver, **calibrate the RC**. Type `cr` command in Serial Monitor and follow the instructions.
-  * **Define the used GPIO pin** in `RC_RX_PIN` parameter.
+* **Check the IMU output using QGroundControl**. Connect to the drone using QGroundControl on your computer. Go to the *Analyze* tab, *MAVLINK Inspector*. Plot the data from the `SCALED_IMU` message. The gyroscope and accelerometer data should change according to the drone movement.
  * **Calibrate the RC** using `cr` command in the console.
  * **Check the controls** using `rc` command. All the controls should change between -1 and 1, and the throttle between 0 and 1.
@@ -112,9 +112,9 @@ You can also work with parameters using `p` command in the console. Parameter na
 ### Define IMU orientation
-The IMU orientation (relative to the drone's axes) is defined using the parameters: `IMU_ROT_ROLL`, `IMU_ROT_PITCH`, and `IMU_ROT_YAW`.
+Use parameters, to define the IMU board axes orientation relative to the drone's axes: `IMU_ROT_ROLL`, `IMU_ROT_PITCH`, and `IMU_ROT_YAW`.
-The drone has *X* axis pointing forward, *Y* axis pointing left, and *Z* axis pointing up, and the supported IMU boards have *X* axis pointing to the mounting holes side and *Z* axis pointing up from the component side:
+The drone has *X* axis pointing forward, *Y* axis pointing left, and *Z* axis pointing up, and the supported IMU boards have *X* axis pointing to the pins side and *Z* axis pointing up from the component side:
 <img src="img/imu-axes.png" width="200">
@@ -122,10 +122,10 @@ Use the following table to set the parameters for common IMU orientations:
 |Orientation|Parameters|Orientation|Parameters|
 |:-:|-|-|-|
-|<img src="img/imu-rot-3.png" width="180">|`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 0    |<img src="img/imu-rot-7.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 0|
+|<img src="img/imu-rot-1.png" width="180">|`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 0    |<img src="img/imu-rot-5.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 0|
-|<img src="img/imu-rot-2.png" width="180">|`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = -1.571|<img src="img/imu-rot-6.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = -1.571|
+|<img src="img/imu-rot-2.png" width="180">|`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 1.571|<img src="img/imu-rot-6.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = -1.571|
-|<img src="img/imu-rot-1.png" width="180">|`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 3.142|<img src="img/imu-rot-5.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 3.142|
+|<img src="img/imu-rot-3.png" width="180">|`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 3.142|<img src="img/imu-rot-7.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 3.142|
-|<img src="img/imu-rot-4.png" width="180"><br>☑️ **Default**|<br>`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 1.571|<img src="img/imu-rot-8.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 1.571|
+|<img src="img/imu-rot-4.png" width="180"><br>☑️ **Default**|<br>`IMU_ROT_ROLL` = 0<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = -1.571|<img src="img/imu-rot-8.png" width="180">|`IMU_ROT_ROLL` = 3.142<br>`IMU_ROT_PITCH` = 0<br>`IMU_ROT_YAW` = 1.571|
 ### Calibrate accelerometer
@@ -138,8 +138,6 @@ Before flight you need to calibrate the accelerometer:
 If using non-default motor pins, set the pin numbers using the parameters: `MOTOR_PIN_FL`, `MOTOR_PIN_FR`, `MOTOR_PIN_RL`, `MOTOR_PIN_RR` (front-left, front-right, rear-left, rear-right respectively).
 Certain ESP32 models (such as ESP32-S3 and ESP32-C3) support a lower maximum PWM frequency; on these boards the parameter `MOT_PWM_FREQ` should be set to 38000 Hz.
 If using brushless motors and ESCs:
 1. Set the appropriate PWM using the parameters: `MOT_PWM_STOP`, `MOT_PWM_MIN`, and `MOT_PWM_MAX` (1000, 1000, and 2000 is typical).
@@ -148,38 +146,27 @@ If using brushless motors and ESCs:
 > [!CAUTION]
 > **Remove the props when configuring the motors!** If improperly configured, you may not be able to stop them.
-### Battery voltage monitoring
+### Check everything works
-ESP32 ADC can measure only up to 3.3 V, so you need to use a voltage divider to monitor the battery voltage. To enable voltage measurement, set the following parameters:
+1. Check the IMU is working: perform `imu` command and check its output:
 1. `PWR_VOLT_PIN` — GPIO pin number where the voltage divider is connected (*-1* to disable).
 2. `PWR_VOLT_SCALE` — voltage divider coefficient (*2* for two equal resistors).
 After this setup, you should see the battery voltage in QGroundControl top panel or using `pw` command in the console.
 ### Important: check everything works
 1. Check the IMU is working: perform `imu` command in the console and check the output:
   * The `status` field should be `OK`.
   * The `rate` field should be about 1000 (Hz).
   * The `accel` and `gyro` fields should change as you move the drone.
   * The `accel bias` and `accel scale` fields should contain calibration parameters (not zeros and ones).
   * The `gyro bias` field should contain estimated gyro bias (not zeros).
   * The `landed` field should be `1` when the drone is still on the ground and `0` when you lift it up.
 2. Check the attitude estimation: connect to the drone using QGroundControl, rotate the drone in different orientations and check if the attitude estimation shown in QGroundControl is correct. Compare your attitude indicator (in the *large vertical* mode) to the video:
    <a href="https://youtu.be/yVRN23-GISU"><img width=300 src="https://i3.ytimg.com/vi/yVRN23-GISU/maxresdefault.jpg"></a>
-3. Perform motor tests. Use the following commands **— remove the propellers before running the tests!**
+3. Perform motor tests in the console. Use the following commands **— remove the propellers before running the tests!**
-   * `mfr` — rotate front right motor (counter-clockwise).
+   * `mfr` — should rotate front right motor (counter-clockwise).
-   * `mfl` — rotate front left motor (clockwise).
+   * `mfl` — should rotate front left motor (clockwise).
-   * `mrl` — rotate rear left motor (counter-clockwise).
+   * `mrl` — should rotate rear left motor (counter-clockwise).
-   * `mrr` — rotate rear right motor (clockwise).
+   * `mrr` — should rotate rear right motor (clockwise).
-   Make sure rotation directions and propeller types match the following diagram:
+   Rotation diagram:
   <img src="img/motors.svg" width=200>
@@ -192,18 +179,6 @@ There are several ways to control the drone's flight: using **smartphone** (Wi-F
 ### Control with a smartphone
 #### Using Mavlink Joystick app (Android)
 <img src="https://github.com/goldarte/mavlink-joystick/blob/master/app_screen.png?raw=true" width="400">
 1. Download and install [Mavlink Joystick app](https://github.com/goldarte/mavlink-joystick/releases/latest).
 2. Power the drone using the battery.
 3. Connect your smartphone to the appeared `flix` Wi-Fi network (password: `flixwifi`).
 4. Open Mavlink Joystick app. It should connect and begin showing the drone's telemetry automatically.
 5. Use the virtual joystick to fly the drone!
 #### Using QGroundControl app
 1. Install [QGroundControl mobile app](https://docs.qgroundcontrol.com/master/en/qgc-user-guide/getting_started/download_and_install.html#android) on your smartphone.
 2. Power the drone using the battery.
 3. Connect your smartphone to the appeared `flix` Wi-Fi network (password: `flixwifi`).
@@ -216,13 +191,11 @@ There are several ways to control the drone's flight: using **smartphone** (Wi-F
 ### Control with a remote control
-If using SBUS-connected remote control you need to enable SBUS and calibrate it:
+Before using remote SBUS-connected remote control, you need to calibrate it:
-1. Connect to the drone using QGroundControl.
+1. Access the console using QGroundControl (recommended) or Serial Monitor.
-2. In parameters, set the `RC_RX_PIN` parameter to the GPIO pin number where the SBUS signal is connected, for example: 4. Negative value disables SBUS.
+2. Type `cr` command and follow the instructions.
-3. Check if the receiver is working using `rc` command in the console.
+3. Use the remote control to fly the drone!
 4. Open the console, type `cr` command and follow the instructions to calibrate the remote control.
 5. Use the remote control to fly the drone!
 ### Control with a USB remote control
@@ -259,11 +232,11 @@ When finished flying, **disarm** the drone, moving the left stick to the bottom
 ### Flight modes
-Flight mode is changed using mode switch on the remote control (if configured) or using the console commands. The main flight mode is *STAB*. In order to change modes using SBUS remote control, set the parameters: `CTL_FLT_MODE_0`, `CTL_FLT_MODE_1`, and `CTL_FLT_MODE_2` to required mode numbers (0 for *RAW*, 1 for *ACRO*, 2 for *STAB*, 3 for *AUTO*).
+Flight mode is changed using mode switch on the remote control or using the command line.
 #### STAB
-In this mode, the drone stabilizes its attitude (orientation). The left stick controls throttle and yaw rate, the right stick controls pitch and roll angles.
+The default mode is *STAB*. In this mode, the drone stabilizes its attitude (orientation). The left stick controls throttle and yaw rate, the right stick controls pitch and roll angles.
 > [!IMPORTANT]
 > The drone doesn't stabilize its position, so slight drift is possible. The pilot should compensate it manually.
@@ -278,9 +251,9 @@ In this mode, the pilot controls the angular rates. This control method is diffi
 #### AUTO
-In this mode, the pilot inputs are ignored (except the mode switch). The drone can be controlled using [pyflix](../tools/pyflix/) Python library, or by modifying the firmware to implement the needed behavior.
+In this mode, the pilot inputs are ignored (except the mode switch, if configured). The drone can be controlled using [pyflix](../tools/pyflix/) Python library, or by modifying the firmware to implement the needed autonomous behavior.
-If the pilot moves the control sticks and mode switch is not configured, the drone will switch back to *STAB* mode.
+If the pilot moves the control sticks, the drone will switch back to *STAB* mode.
 ## Wi-Fi configuration
@@ -290,8 +263,11 @@ The Wi-Fi mode is chosen using `WIFI_MODE` parameter in QGroundControl or in the
 * `0` — Wi-Fi is disabled.
 * `1` — Access Point mode *(AP)* — the drone creates a Wi-Fi network.
-* `2` — Client mode *(STA)* — the drone connects to an existing Wi-Fi network (may cause additional delays, so generally not recommended).
+* `2` — Client mode *(STA)* — the drone connects to an existing Wi-Fi network.
-* `3` — ESP-NOW mode — the drone uses ESP-NOW protocol for communication.
+* `3` — *ESP-NOW (not implemented yet)*.
 > [!WARNING]
 > Tests showed that Client mode may cause **additional delays** in remote control (due to retranslations), so it's generally not recommended.
 The SSID and password are configured using the `ap` and `sta` console commands:
@@ -313,37 +289,6 @@ Disabling Wi-Fi:
 p WIFI_MODE 0
 ```
 ### Using ESP-NOW
 [ESP-NOW](https://docs.espressif.com/projects/esp-idf/en/stable/esp32/api-reference/network/esp_now.html) is a low level wireless communication protocol. It can provide lower latency, better reliability, and longer range than Wi-Fi. However, it requires a second ESP32 board to be used as a proxy for the computer.
 <img src="img/espnow-connection.jpg" width="600">
 To setup ESP-NOW communication:
 1. Flash the second ESP32 board with ESP-NOW proxy sketch: [`tools/espnow-proxy/espnow-proxy.ino`](../tools/espnow-proxy/espnow-proxy.ino). Use Arduino IDE or command line: `make upload_proxy`.
 2. Open Serial Monitor or use `make monitor` command. The ESP32 will print its MAC address and generated encryption key, for example:
   ```
   espnow 7a:c8:e3:eb:bf:e9 &PiuSysxP9+$L&5E
   ```
   Run this line as a console command on each drone you want to bind to this proxy board.
 3. Set the `WIFI_MODE` parameter to `3` on the drone:
   ```
   p WIFI_MODE 3
   ```
 4. Go to the QGroundControl menu ⇒ *Application Settings* ⇒ *Comm Links*, add new link with the following settings:
   * Name: ESP32.
   * Type: Serial.
   * Serial Port: choose the port of the proxy ESP32 board, e. g. `/dev/cu.usbserial-0001`.
   * Baud Rate: 115200.
 5. Click *Save*. QGroundControl should connect to the drone using ESP-NOW and begin showing the telemetry.
 ## Flight log
 After the flight, you can download the flight log for analysis wirelessly. Use the following command on your computer for that:
@@ -4,49 +4,6 @@ This page contains user-built drones based on the Flix project. Publish your pro
 ---
 Author: [Ina Tix](https://t.me/ina_tix).<br>
 Description: XR2981 based DC-DC converter, ELRS MINI 2.4GHz RX SX1280 receiver (SBUS interface), Radiomaster TX12 remote control.<br>
 [Flight validation](https://drive.google.com/file/d/1yqkKNuz4R_yxGqUNQxVpixJbXqEEcUSj/view?usp=share_link).
 <img src="img/user/ina_tix/1.jpg" height=200> <img src="img/user/ina_tix/2.jpg" height=200> <img src="img/user/ina_tix/3.jpg" height=200>
 ---
 Author: Oleg Kalachev.<br>
 Description: the first attempt on making an official PCB based Flix drone (Flix2 board). The IMU is not working on this version, so an external MPU-6050 board was used, therefore considered as **Flix version 1.5**.<br>
 [Flight video](https://drive.google.com/file/d/1R7tuUsFmPY0CGcOCFfMFaCp9kR49K3bl/view?usp=sharing).
 <img src="img/flix1.5.jpg" width=300>
 ---
 Author: [FanBy0ru](https://https://github.com/FanBy0ru).<br>
 Description: custom 3D-printed frame.<br>
 Frame STLs and flight validation: https://cults3d.com/en/3d-model/gadget/armature-pour-flix-drone.
 <img src="img/user/fanby0ru/1.jpg" height=200> <img src="img/user/fanby0ru/2.jpg" height=200>
 ---
 Author: Ivan44 Phalko.<br>
 Description: custom PCB, cusom test bench.<br>
 [Flight validation](https://drive.google.com/file/d/17DNDJ1gPmCmDRAwjedCbJ9RXAyqMqqcX/view?usp=sharing).
 <img src="img/user/phalko/1.jpg" height=200> <img src="img/user/phalko/2.jpg" height=200> <img src="img/user/phalko/3.jpg" height=200>
 ---
 Author: **Arkadiy "Arky" Matsekh**, Foucault Dynamics, Gold Coast, Australia.<br>
 The drone was built for the University of Queensland industry-led Master's capstone project.
 **Flight video:**
 <a href="https://drive.google.com/file/d/1NNYSVXBY-w0JjCo07D8-PgnVq3ca9plj/view?usp=sharing"><img height=300 src="img/user/arkymatsekh/video.jpg"></a>
 <img src="img/user/arkymatsekh/1.jpg" height=150> <img src="img/user/arkymatsekh/2.jpg" height=150> <img src="img/user/arkymatsekh/3.jpg" height=150>
 ---
 Author: [goldarte](https://t.me/goldarte).<br>
 <img src="img/user/goldarte/1.jpg" height=150> <img src="img/user/goldarte/2.jpg" height=150>
@@ -10,24 +10,21 @@
 extern const int MOTOR_REAR_LEFT, MOTOR_REAR_RIGHT, MOTOR_FRONT_RIGHT, MOTOR_FRONT_LEFT;
 extern const int RAW, ACRO, STAB, AUTO;
 extern const int W_AP, W_STA, W_ESPNOW;
 extern float t, dt, loopRate;
 extern uint16_t channels[16];
 extern float controlTime;
 extern int mode;
 extern bool armed;
 extern LowPassFilter<Vector> gyroBiasFilter;
 extern float voltage;
 const char* motd =
 "\nWelcome to\n"
 " _______  __       __  ___   ___\n"
 "|   ____||  |     |  | \\  \\ /  /\n"
 "|  |__   |  |     |  |  \\  V  /\n"
 "|   __|  |  |     |  |   >   <\n"
 "|  |     |  `----.|  |  /  .  \\\n"
 "|__|     |_______||__| /__/ \\__\\\n\n"
 "(C) Oleg Kalachev\n"
 "https://github.com/okalachev/flix\n\n"
 "Commands:\n\n"
 "help - show help\n"
 "p - show all parameters\n"
@@ -42,11 +39,9 @@ const char* motd =
 "disarm - disarm the drone\n"
 "raw/stab/acro/auto - set mode\n"
 "rc - show RC data\n"
 "pw - show power info\n"
 "wifi - show Wi-Fi info\n"
 "ap <ssid> <password> - setup Wi-Fi access point\n"
 "sta <ssid> <password> - setup Wi-Fi client mode\n"
 "espnow <mac> [<key>] - setup ESP-NOW peer\n"
 "mot - show motor output\n"
 "log [dump] - print log header [and data]\n"
 "cr - calibrate RC\n"
@@ -140,16 +135,12 @@ void doCommand(String str, bool echo = false) {
 		print("time: %.1f\n", controlTime);
 		print("mode: %s\n", getModeName());
 		print("armed: %d\n", armed);
 	} else if (command == "pw") {
 		print("Voltage: %.1f V\n", voltage);
 	} else if (command == "wifi") {
 		printWiFiInfo();
 	} else if (command == "ap") {
-		configWiFi(W_AP, arg0.c_str(), arg1.c_str());
+		configWiFi(true, arg0.c_str(), arg1.c_str());
 	} else if (command == "sta") {
-		configWiFi(W_STA, arg0.c_str(), arg1.c_str());
+		configWiFi(false, arg0.c_str(), arg1.c_str());
 	} else if (command == "espnow") {
 		configWiFi(W_ESPNOW, arg0.c_str(), arg1.c_str());
 	} else if (command == "mot") {
 		print("front-right %g front-left %g rear-right %g rear-left %g\n",
 			motors[MOTOR_FRONT_RIGHT], motors[MOTOR_FRONT_LEFT], motors[MOTOR_REAR_RIGHT], motors[MOTOR_REAR_LEFT]);
@@ -173,7 +164,6 @@ void doCommand(String str, bool echo = false) {
 		print("Chip: %s\n", ESP.getChipModel());
 		print("Temperature: %.1f °C\n", temperatureRead());
 		print("Free heap: %d\n", ESP.getFreeHeap());
 		print("Firmware: " __DATE__ " " __TIME__ "\n");
 		// Print tasks table
 		print("Num  Task                Stack  Prio  Core  CPU%%\n");
 		int taskCount = uxTaskGetNumberOfTasks();
@@ -184,7 +174,7 @@ void doCommand(String str, bool echo = false) {
 			String core = systemState[i].xCoreID == tskNO_AFFINITY ? "*" : String(systemState[i].xCoreID);
 			int cpuPercentage = systemState[i].ulRunTimeCounter / (totalRunTime / 100);
 			print("%-5d%-20s%-7d%-6d%-6s%d\n",systemState[i].xTaskNumber, systemState[i].pcTaskName,
-				systemState[i].usStackHighWaterMark, systemState[i].uxCurrentPriority, core.c_str(), cpuPercentage);
+				systemState[i].usStackHighWaterMark, systemState[i].uxCurrentPriority, core, cpuPercentage);
 		}
 		delete[] systemState;
 #endif
@@ -52,7 +52,6 @@ PID pitchPID(PITCH_P, PITCH_I, PITCH_D);
 PID yawPID(YAW_P, 0, 0);
 Vector maxRate(ROLLRATE_MAX, PITCHRATE_MAX, YAWRATE_MAX);
 float tiltMax = TILT_MAX;
 int flightModes[] = {STAB, STAB, STAB}; // map for rc mode switch
 extern const int MOTOR_REAR_LEFT, MOTOR_REAR_RIGHT, MOTOR_FRONT_RIGHT, MOTOR_FRONT_LEFT;
 extern float controlRoll, controlPitch, controlThrottle, controlYaw, controlMode;
@@ -66,9 +65,9 @@ void control() {
 }
 void interpretControls() {
-	if (controlMode < 0.25) mode = flightModes[0];
+	if (controlMode < 0.25) mode = STAB;
-	else if (controlMode <= 0.75) mode = flightModes[1];
+	if (controlMode < 0.75) mode = STAB;
-	else if (controlMode > 0.75) mode = flightModes[2];
+	if (controlMode > 0.75) mode = STAB;
 	if (mode == AUTO) return; // pilot is not effective in AUTO mode
@@ -149,25 +148,12 @@ void controlTorque() {
 	motors[MOTOR_REAR_LEFT] = thrustTarget + torqueTarget.x + torqueTarget.y - torqueTarget.z;
 	motors[MOTOR_REAR_RIGHT] = thrustTarget - torqueTarget.x + torqueTarget.y + torqueTarget.z;
 	desaturate(motors[MOTOR_FRONT_LEFT], motors[MOTOR_FRONT_RIGHT], motors[MOTOR_REAR_LEFT], motors[MOTOR_REAR_RIGHT]);
 	motors[0] = constrain(motors[0], 0, 1);
 	motors[1] = constrain(motors[1], 0, 1);
 	motors[2] = constrain(motors[2], 0, 1);
 	motors[3] = constrain(motors[3], 0, 1);
 }
 void desaturate(float& a, float& b, float& c, float& d) {
 	float maxThrust = max(max(a, b), max(c, d));
 	if (maxThrust > 1) {
 		float diff = maxThrust - 1;
 		a -= diff;
 		b -= diff;
 		c -= diff;
 		d -= diff;
 	}
 }
 const char* getModeName() {
 	switch (mode) {
 		case RAW: return "RAW";
@@ -1,7 +1,7 @@
 // Copyright (c) 2023 Oleg Kalachev <okalachev@gmail.com>
 // Repository: https://github.com/okalachev/flix
-// Attitude estimation using gyro and accelerometer
+// Attitude estimation from gyro and accelerometer
 #include "quaternion.h"
 #include "vector.h"
@@ -13,13 +13,11 @@ Quaternion attitude; // estimated attitude
 bool landed;
 float accWeight = 0.003;
 float levelWeight = 0.0002;
 LowPassFilter<Vector> ratesFilter(0.2); // cutoff frequency ~ 40 Hz
 void estimate() {
 	applyGyro();
 	applyAcc();
 	applyLevel();
 }
 void applyGyro() {
@@ -44,12 +42,3 @@ void applyAcc() {
 	// apply correction
 	attitude = Quaternion::rotate(attitude, Quaternion::fromRotationVector(correction));
 }
 void applyLevel() {
 	if (landed) return;
 	// assume the pilot keeps the drone more or less level in flight
 	Vector up = Quaternion::rotateVector(Vector(0, 0, 1), attitude);
 	Vector correction = Vector::rotationVectorBetween(Vector(0, 0, 1), up) * levelWeight;
 	attitude = Quaternion::rotate(attitude, Quaternion::fromRotationVector(correction));
 }
@@ -18,11 +18,11 @@ extern float motors[4];
 void setup() {
 	Serial.begin(115200);
 	print("Initializing flix\n");
 	disableBrownOut();
 	setupParameters();
 	setupPower();
 	setupLED();
 	setLED(true);
 	setupMotors();
 	setLED(true);
 	setupWiFi();
 	setupIMU();
 	setupRC();
@@ -39,7 +39,6 @@ void loop() {
 	sendMotors();
 	handleInput();
 	processMavlink();
 	readVoltage();
 	logData();
 	syncParameters();
 }
@@ -10,7 +10,7 @@
 #include "util.h"
 MPU9250 imu(SPI);
-Vector imuRotation(0, 0, PI / 2); // imu orientation as Euler angles
+Vector imuRotation(0, 0, -PI / 2); // imu orientation as Euler angles
 Vector gyro; // gyroscope output, rad/s
 Vector gyroBias;
@@ -121,7 +121,7 @@ void printIMUInfo() {
 	print("model: %s\n", imu.getModel());
 	print("who am I: 0x%02X\n", imu.whoAmI());
 	print("rate: %.0f\n", loopRate);
-	print("gyro: %f %f %f\n", gyro.x, gyro.y, gyro.z);
+	print("gyro: %f %f %f\n", rates.x, rates.y, rates.z);
 	print("acc: %f %f %f\n", acc.x, acc.y, acc.z);
 	imu.waitForData();
 	Vector rawGyro, rawAcc;
@@ -14,10 +14,6 @@ public:
 	LowPassFilter(float alpha): alpha(alpha) {};
 	T update(const T input) {
 		if (!init) {
 			init = true;
 			return output = input;
 		}
 		return output += alpha * (input - output);
 	}
@@ -26,9 +22,6 @@ public:
 	}
 	void reset() {
-		init = false;
+		output = T(); // set to zero
 	}
 private:
 	bool init = false;
 };
@@ -7,14 +7,12 @@
 #include "util.h"
 extern float controlTime;
 extern float voltage;
 int mavlinkSysId = 1;
 Rate telemetryFast(10);
 Rate telemetrySlow(2);
 bool mavlinkConnected = false;
 String mavlinkPrintBuffer;
 int mavlinkSysId = 1;
 Rate telemetryFast(10);
 Rate telemetrySlow(2);
 void processMavlink() {
 	sendMavlink();
@@ -40,19 +38,12 @@ void sendMavlink() {
 		mavlink_msg_extended_sys_state_pack(mavlinkSysId, MAV_COMP_ID_AUTOPILOT1, &msg,
 			MAV_VTOL_STATE_UNDEFINED, landed ? MAV_LANDED_STATE_ON_GROUND : MAV_LANDED_STATE_IN_AIR);
 		sendMessage(&msg);
 		uint16_t voltages[] = {voltage * 1000, UINT16_MAX, UINT16_MAX, UINT16_MAX, UINT16_MAX, UINT16_MAX, UINT16_MAX, UINT16_MAX, UINT16_MAX, UINT16_MAX};
 		uint16_t voltagesExt[] = {0, 0, 0, 0};
 		float remaining = constrain(mapf(voltage, 3.4, 4.2, 0, 1), 0, 1);
 		mavlink_msg_battery_status_pack(mavlinkSysId, MAV_COMP_ID_AUTOPILOT1, &msg, 0, MAV_BATTERY_FUNCTION_ALL,
 			MAV_BATTERY_TYPE_LIPO, INT16_MAX, voltages, -1, -1, -1, remaining * 100, 0, MAV_BATTERY_CHARGE_STATE_OK, voltagesExt, 0, 0);
 		if (valid(voltage)) sendMessage(&msg);
 	}
 	if (telemetryFast && mavlinkConnected) {
-		const float offset[] = {0, 0, 0, 0};
+		const float zeroQuat[] = {0, 0, 0, 0};
 		mavlink_msg_attitude_quaternion_pack(mavlinkSysId, MAV_COMP_ID_AUTOPILOT1, &msg,
-			time, attitude.w, attitude.x, -attitude.y, -attitude.z, rates.x, -rates.y, -rates.z, offset); // convert to frd
+			time, attitude.w, attitude.x, -attitude.y, -attitude.z, rates.x, -rates.y, -rates.z, zeroQuat); // convert to frd
 		sendMessage(&msg);
 		mavlink_msg_rc_channels_raw_pack(mavlinkSysId, MAV_COMP_ID_AUTOPILOT1, &msg, controlTime * 1000, 0,
@@ -65,7 +56,7 @@ void sendMavlink() {
 		sendMessage(&msg);
 		mavlink_msg_scaled_imu_pack(mavlinkSysId, MAV_COMP_ID_AUTOPILOT1, &msg, time,
-			acc.x / ONE_G * 1000, -acc.y / ONE_G * 1000, -acc.z / ONE_G * 1000, // convert to frd
+			acc.x * 1000, -acc.y * 1000, -acc.z * 1000, // convert to frd
 			gyro.x * 1000, -gyro.y * 1000, -gyro.z * 1000,
 			0, 0, 0, 0);
 		sendMessage(&msg);
@@ -24,7 +24,7 @@ void setupMotors() {
 	// configure pins
 	for (int i = 0; i < 4; i++) {
 		ledcAttach(motorPins[i], pwmFrequency, pwmResolution);
-		pwmFrequency = ledcChangeFrequency(motorPins[i], pwmFrequency, pwmResolution); // when reconfiguring
+		pwmFrequency = ledcChangeFrequency(motorPins[i], pwmFrequency, pwmResolution); // if re-initializing
 	}
 	sendMotors();
 	print("Motors initialized\n");
@@ -54,7 +54,7 @@ bool motorsActive() {
 void testMotor(int n) {
 	print("Testing motor %d\n", n);
-	motors[n] = 0.2;
+	motors[n] = 1;
 	delay(50); // ESP32 may need to wait until the end of the current cycle to change duty https://github.com/espressif/arduino-esp32/issues/5306
 	sendMotors();
 	pause(3);
@@ -6,26 +6,21 @@
 #include <Preferences.h>
 #include "util.h"
-extern int channelZero[16];
+extern float channelZero[16];
-extern int channelMax[16];
+extern float channelMax[16];
-extern int rollChannel, pitchChannel, throttleChannel, yawChannel, armedChannel, modeChannel;
+extern float rollChannel, pitchChannel, throttleChannel, yawChannel, armedChannel, modeChannel;
-extern int rcRxPin;
+extern int wifiMode, udpLocalPort, udpRemotePort;
 extern int wifiMode, wifiLongRange, udpLocalPort, udpRemotePort, espnowChannel;
 extern float rcLossTimeout, descendTime;
 extern int voltagePin;
 extern float voltageScale;
 extern LowPassFilter<float> voltageFilter;
 Preferences storage;
 struct Parameter {
-	const char *name; // max length is 15
+	const char *name; // max length is 15 (Preferences key limit)
 	bool integer;
-	union { float *f; int *i; }; // pointer to the variable
+	union { float *f; int *i; }; // pointer to variable
 	float cache; // what's stored in flash
-	void (*callback)(); // called after parameter change
+	Parameter(const char *name, float *variable) : name(name), integer(false), f(variable) {};
-	Parameter(const char *name, float *variable, void (*callback)() = nullptr) : name(name), integer(false), f(variable), callback(callback) {};
+	Parameter(const char *name, int *variable) : name(name), integer(true), i(variable) {};
 	Parameter(const char *name, int *variable, void (*callback)() = nullptr) : name(name), integer(true), i(variable), callback(callback) {};
 	float getValue() const { return integer ? *i : *f; };
 	void setValue(const float value) { if (integer) *i = value; else *f = value; };
 };
@@ -36,16 +31,13 @@ Parameter parameters[] = {
 	{"CTL_R_RATE_I", &rollRatePID.i},
 	{"CTL_R_RATE_D", &rollRatePID.d},
 	{"CTL_R_RATE_WU", &rollRatePID.windup},
 	{"CTL_R_RATE_D_A", &rollRatePID.lpf.alpha},
 	{"CTL_P_RATE_P", &pitchRatePID.p},
 	{"CTL_P_RATE_I", &pitchRatePID.i},
 	{"CTL_P_RATE_D", &pitchRatePID.d},
 	{"CTL_P_RATE_WU", &pitchRatePID.windup},
 	{"CTL_P_RATE_D_A", &pitchRatePID.lpf.alpha},
 	{"CTL_Y_RATE_P", &yawRatePID.p},
 	{"CTL_Y_RATE_I", &yawRatePID.i},
 	{"CTL_Y_RATE_D", &yawRatePID.d},
 	{"CTL_Y_RATE_D_A", &yawRatePID.lpf.alpha},
 	{"CTL_R_P", &rollPID.p},
 	{"CTL_R_I", &rollPID.i},
 	{"CTL_R_D", &rollPID.d},
@@ -57,9 +49,6 @@ Parameter parameters[] = {
 	{"CTL_R_RATE_MAX", &maxRate.x},
 	{"CTL_Y_RATE_MAX", &maxRate.z},
 	{"CTL_TILT_MAX", &tiltMax},
 	{"CTL_FLT_MODE_0", &flightModes[0]},
 	{"CTL_FLT_MODE_1", &flightModes[1]},
 	{"CTL_FLT_MODE_2", &flightModes[2]},
 	// imu
 	{"IMU_ROT_ROLL", &imuRotation.x},
 	{"IMU_ROT_PITCH", &imuRotation.y},
@@ -73,20 +62,18 @@ Parameter parameters[] = {
 	{"IMU_GYRO_BIAS_A", &gyroBiasFilter.alpha},
 	// estimate
 	{"EST_ACC_WEIGHT", &accWeight},
 	{"EST_LVL_WEIGHT", &levelWeight},
 	{"EST_RATES_LPF_A", &ratesFilter.alpha},
 	// motors
-	{"MOT_PIN_FL", &motorPins[MOTOR_FRONT_LEFT], setupMotors},
+	{"MOT_PIN_FL", &motorPins[MOTOR_FRONT_LEFT]},
-	{"MOT_PIN_FR", &motorPins[MOTOR_FRONT_RIGHT], setupMotors},
+	{"MOT_PIN_FR", &motorPins[MOTOR_FRONT_RIGHT]},
-	{"MOT_PIN_RL", &motorPins[MOTOR_REAR_LEFT], setupMotors},
+	{"MOT_PIN_RL", &motorPins[MOTOR_REAR_LEFT]},
-	{"MOT_PIN_RR", &motorPins[MOTOR_REAR_RIGHT], setupMotors},
+	{"MOT_PIN_RR", &motorPins[MOTOR_REAR_RIGHT]},
-	{"MOT_PWM_FREQ", &pwmFrequency, setupMotors},
+	{"MOT_PWM_FREQ", &pwmFrequency},
-	{"MOT_PWM_RES", &pwmResolution, setupMotors},
+	{"MOT_PWM_RES", &pwmResolution},
 	{"MOT_PWM_STOP", &pwmStop},
 	{"MOT_PWM_MIN", &pwmMin},
 	{"MOT_PWM_MAX", &pwmMax},
 	// rc
 	{"RC_RX_PIN", &rcRxPin, setupRC},
 	{"RC_ZERO_0", &channelZero[0]},
 	{"RC_ZERO_1", &channelZero[1]},
 	{"RC_ZERO_2", &channelZero[2]},
@@ -110,27 +97,19 @@ Parameter parameters[] = {
 	{"RC_MODE", &modeChannel},
 	// wifi
 	{"WIFI_MODE", &wifiMode},
-	{"WIFI_PORT_LOC", &udpLocalPort},
+	{"WIFI_LOC_PORT", &udpLocalPort},
-	{"WIFI_PORT_REM", &udpRemotePort},
+	{"WIFI_REM_PORT", &udpRemotePort},
 	{"WIFI_LONG_RANGE", &wifiLongRange},
 	// espnow
 	{"ESPNOW_CHANNEL", &espnowChannel},
 	// mavlink
 	{"MAV_SYS_ID", &mavlinkSysId},
 	{"MAV_RATE_SLOW", &telemetrySlow.rate},
 	{"MAV_RATE_FAST", &telemetryFast.rate},
 	// power
 	{"PWR_VOLT_PIN", &voltagePin, setupPower},
 	{"PWR_VOLT_SCALE", &voltageScale},
 	{"PWR_VOLT_LPF_A", &voltageFilter.alpha},
 	// safety
 	{"SF_RC_LOSS_TIME", &rcLossTimeout},
 	{"SF_DESCEND_TIME", &descendTime},
 };
 void setupParameters() {
-	print("Setup parameters\n");
+	storage.begin("flix", false);
 	storage.begin("flix");
 	// Read parameters from storage
 	for (auto &parameter : parameters) {
 		if (!storage.isKey(parameter.name)) {
@@ -141,6 +120,11 @@ void setupParameters() {
 	}
 }
 void afterParameterChange(String name, const float value) {
 	if (name == "MOT_PWM_FREQ" || name == "MOT_PWM_RES") setupMotors();
 	if (name == "MOT_PIN_FL" || name == "MOT_PIN_FR" || name == "MOT_PIN_RL" || name == "MOT_PIN_RR") setupMotors();
 }
 int parametersCount() {
 	return sizeof(parameters) / sizeof(parameters[0]);
 }
@@ -169,7 +153,7 @@ bool setParameter(const char *name, const float value) {
 		if (strcasecmp(parameter.name, name) == 0) {
 			if (parameter.integer && !isfinite(value)) return false; // can't set integer to NaN or Inf
 			parameter.setValue(value);
-			if (parameter.callback) parameter.callback();
+			afterParameterChange(name, value);
 			return true;
 		}
 	}
@@ -183,7 +167,8 @@ void syncParameters() {
 	for (auto &parameter : parameters) {
 		if (parameter.getValue() == parameter.cache) continue; // no change
-		if (isnan(parameter.getValue()) && isnan(parameter.cache)) continue; // both are NAN
+		if (isnan(parameter.getValue()) && isnan(parameter.cache)) continue; // both are NaN
 		if (isinf(parameter.getValue()) && isinf(parameter.cache)) continue; // both are Inf
 		storage.putFloat(parameter.name, parameter.getValue());
 		parameter.cache = parameter.getValue(); // update cache
@@ -1,28 +0,0 @@
 // Copyright (c) 2026 Oleg Kalachev <okalachev@gmail.com>
 // Repository: https://github.com/okalachev/flix
 // Power management
 #include <soc/soc.h>
 #include <soc/rtc_cntl_reg.h>
 #include "lpf.h"
 #include "util.h"
 float voltage = NAN;
 LowPassFilter<float> voltageFilter(0.2);
 int voltagePin = -1;
 float voltageScale = 2;
 void setupPower() {
 	REG_CLR_BIT(RTC_CNTL_BROWN_OUT_REG, RTC_CNTL_BROWN_OUT_ENA); // disable reset on low voltage
 	if (digitalPinToAnalogChannel(voltagePin) == -1) voltagePin = -1; // test ADC pin
 }
 void readVoltage() {
 	if (voltagePin < 0) return;
 	static Rate rate(10);
 	if (!rate) return;
 	float v = analogReadMilliVolts(voltagePin) * voltageScale / 1000.0f;
 	voltage = voltageFilter.update(v);
 }
@@ -6,27 +6,25 @@
 #include <SBUS.h>
 #include "util.h"
-SBUS rc(Serial1);
+SBUS rc(Serial2);
 int rcRxPin = -1; // -1 means disabled
 uint16_t channels[16]; // raw rc channels
-int channelZero[16]; // calibration zero values
+float channelZero[16]; // calibration zero values
-int channelMax[16]; // calibration max values
+float channelMax[16]; // calibration max values
 float controlRoll, controlPitch, controlYaw, controlThrottle; // pilot's inputs, range [-1, 1]
 float controlMode = NAN;
 float controlTime = NAN; // time of the last controls update
-int rollChannel = -1, pitchChannel = -1, throttleChannel = -1, yawChannel = -1, modeChannel = -1; // channel mapping
+// Channels mapping (nan means not assigned):
 float rollChannel = NAN, pitchChannel = NAN, throttleChannel = NAN, yawChannel = NAN, modeChannel = NAN;
 void setupRC() {
 	if (rcRxPin < 0) return;
 	print("Setup RC\n");
-	rc.begin(rcRxPin);
+	rc.begin();
 }
 bool readRC() {
 	if (rcRxPin < 0) return false;
 	if (rc.read()) {
 		SBUSData data = rc.data();
 		for (int i = 0; i < 16; i++) channels[i] = data.ch[i]; // copy channels data
@@ -43,34 +41,30 @@ void normalizeRC() {
 		controls[i] = mapf(channels[i], channelZero[i], channelMax[i], 0, 1);
 	}
 	// Update control values
-	controlRoll = rollChannel < 0 ? 0 : controls[rollChannel];
+	controlRoll = rollChannel >= 0 ? controls[(int)rollChannel] : 0;
-	controlPitch = pitchChannel < 0 ? 0 : controls[pitchChannel];
+	controlPitch = pitchChannel >= 0 ? controls[(int)pitchChannel] : 0;
-	controlYaw = yawChannel < 0 ? 0 : controls[yawChannel];
+	controlYaw = yawChannel >= 0 ? controls[(int)yawChannel] : 0;
-	controlThrottle = throttleChannel < 0 ? 0 : controls[throttleChannel];
+	controlThrottle = throttleChannel >= 0 ? controls[(int)throttleChannel] : 0;
-	controlMode = modeChannel < 0 ? NAN : controls[modeChannel]; // mode control is ineffective if not mapped
+	controlMode = modeChannel >= 0 ? controls[(int)modeChannel] : NAN; // mode switch should not have affect if not set
 }
 void calibrateRC() {
-	if (rcRxPin < 0) {
+	uint16_t zero[16];
-		print("RC_RX_PIN = %d, set the RC pin!\n", rcRxPin);
+	uint16_t center[16];
-		return;
+	uint16_t max[16];
 	}
 	uint16_t zero[16]; // for zero positions
 	uint16_t center[16]; // for center positions
 	uint16_t _[16]; // for unused data
 	print("1/8 Calibrating RC: put all switches to default positions [3 sec]\n");
 	pause(3);
-	calibrateRCChannel(NULL, _, zero, "2/8 Move sticks [3 sec]\n...     ...\n...     .o.\n.o.     ...\n");
+	calibrateRCChannel(NULL, zero, zero, "2/8 Move sticks [3 sec]\n...     ...\n...     .o.\n.o.     ...\n");
-	calibrateRCChannel(&throttleChannel, zero, _, "3/8 Move sticks [3 sec]\n.o.     ...\n...     .o.\n...     ...\n");
+	calibrateRCChannel(NULL, center, center, "3/8 Move sticks [3 sec]\n...     ...\n.o.     .o.\n...     ...\n");
-	calibrateRCChannel(NULL, _, center, "4/8 Move sticks [3 sec]\n...     ...\n.o.     .o.\n...     ...\n");
+	calibrateRCChannel(&throttleChannel, zero, max, "4/8 Move sticks [3 sec]\n.o.     ...\n...     .o.\n...     ...\n");
-	calibrateRCChannel(&yawChannel, center, _, "5/8 Move sticks [3 sec]\n...     ...\n..o     .o.\n...     ...\n");
+	calibrateRCChannel(&yawChannel, center, max, "5/8 Move sticks [3 sec]\n...     ...\n..o     .o.\n...     ...\n");
-	calibrateRCChannel(&pitchChannel, zero, _, "6/8 Move sticks [3 sec]\n...     .o.\n...     ...\n.o.     ...\n");
+	calibrateRCChannel(&pitchChannel, zero, max, "6/8 Move sticks [3 sec]\n...     .o.\n...     ...\n.o.     ...\n");
-	calibrateRCChannel(&rollChannel, zero, _, "7/8 Move sticks [3 sec]\n...     ...\n...     ..o\n.o.     ...\n");
+	calibrateRCChannel(&rollChannel, zero, max, "7/8 Move sticks [3 sec]\n...     ...\n...     ..o\n.o.     ...\n");
-	calibrateRCChannel(&modeChannel, zero, _, "8/8 Put mode switch to max [3 sec]\n");
+	calibrateRCChannel(&modeChannel, zero, max, "8/8 Put mode switch to max [3 sec]\n");
 	printRCCalibration();
 }
-void calibrateRCChannel(int *channel, uint16_t in[16], uint16_t out[16], const char *str) {
+void calibrateRCChannel(float *channel, uint16_t in[16], uint16_t out[16], const char *str) {
 	print("%s", str);
 	pause(3);
 	for (int i = 0; i < 30; i++) readRC(); // try update 30 times max
@@ -91,15 +85,15 @@ void calibrateRCChannel(int *channel, uint16_t in[16], uint16_t out[16], const c
 		channelZero[ch] = in[ch];
 		channelMax[ch] = out[ch];
 	} else {
-		*channel = -1;
+		*channel = NAN;
 	}
 }
 void printRCCalibration() {
 	print("Control   Ch     Zero   Max\n");
-	print("Roll      %-7d%-7d%-7d\n", rollChannel, rollChannel < 0 ? 0 : channelZero[rollChannel], rollChannel < 0 ? 0 : channelMax[rollChannel]);
+	print("Roll      %-7g%-7g%-7g\n", rollChannel, rollChannel >= 0 ? channelZero[(int)rollChannel] : NAN, rollChannel >= 0 ? channelMax[(int)rollChannel] : NAN);
-	print("Pitch     %-7d%-7d%-7d\n", pitchChannel, pitchChannel < 0 ? 0 : channelZero[pitchChannel], pitchChannel < 0 ? 0 : channelMax[pitchChannel]);
+	print("Pitch     %-7g%-7g%-7g\n", pitchChannel, pitchChannel >= 0 ? channelZero[(int)pitchChannel] : NAN, pitchChannel >= 0 ? channelMax[(int)pitchChannel] : NAN);
-	print("Yaw       %-7d%-7d%-7d\n", yawChannel, yawChannel < 0 ? 0 : channelZero[yawChannel], yawChannel < 0 ? 0 : channelMax[yawChannel]);
+	print("Yaw       %-7g%-7g%-7g\n", yawChannel, yawChannel >= 0 ? channelZero[(int)yawChannel] : NAN, yawChannel >= 0 ? channelMax[(int)yawChannel] : NAN);
-	print("Throttle  %-7d%-7d%-7d\n", throttleChannel, throttleChannel < 0 ? 0 : channelZero[throttleChannel], throttleChannel < 0 ? 0 : channelMax[throttleChannel]);
+	print("Throttle  %-7g%-7g%-7g\n", throttleChannel, throttleChannel >= 0 ? channelZero[(int)throttleChannel] : NAN, throttleChannel >= 0 ? channelMax[(int)throttleChannel] : NAN);
-	print("Mode      %-7d%-7d%-7d\n", modeChannel, modeChannel < 0 ? 0 : channelZero[modeChannel], modeChannel < 0 ? 0 : channelMax[modeChannel]);
+	print("Mode      %-7g%-7g%-7g\n", modeChannel, modeChannel >= 0 ? channelZero[(int)modeChannel] : NAN, modeChannel >= 0 ? channelMax[(int)modeChannel] : NAN);
 }
@@ -37,8 +37,8 @@ void descend() {
 void autoFailsafe() {
 	static float roll, pitch, yaw, throttle;
 	if (roll != controlRoll || pitch != controlPitch || yaw != controlYaw || abs(throttle - controlThrottle) > 0.05) {
-		// controls changed and mode switch is not configured
+		// controls changed
-		if (mode == AUTO && invalid(controlMode)) mode = STAB; // regain control by the pilot
+		if (mode == AUTO) mode = STAB; // regain control by the pilot
 	}
 	roll = controlRoll;
 	pitch = controlPitch;
@@ -6,7 +6,8 @@
 #pragma once
 #include <math.h>
-#include <ESP32_NOW_Serial.h>
+#include <soc/soc.h>
 #include <soc/rtc_cntl_reg.h>
 const float ONE_G = 9.80665;
 extern float t;
@@ -34,29 +35,21 @@ float wrapAngle(float angle) {
 	return angle;
 }
 // Disable reset on low voltage
 void disableBrownOut() {
 	REG_CLR_BIT(RTC_CNTL_BROWN_OUT_REG, RTC_CNTL_BROWN_OUT_ENA);
 }
 // Trim and split string by spaces
 void splitString(String& str, String& token0, String& token1, String& token2) {
 	str.trim();
 	if (str.isEmpty()) return;
 	char chars[str.length() + 1];
 	str.toCharArray(chars, str.length() + 1);
 	token0 = strtok(chars, " ");
-	token1 = strtok(NULL, " ");
+	token1 = strtok(NULL, " "); // String(NULL) creates empty string
 	token2 = strtok(NULL, "");
 	if (token1.c_str() == NULL) token1 = "";
 	if (token2.c_str() == NULL) token2 = "";
 }
 // Simplified ESP-NOW Serial without tx buffering and resends
 class ESPNOWSerial : public ESP_NOW_Serial_Class {
 public:
 	using ESP_NOW_Serial_Class::ESP_NOW_Serial_Class;
 	void onSent(bool success) override {} // disable resends
 	size_t write(const uint8_t *data, size_t len) override {
 		return ESP_NOW_Peer::send(data, len); // pure send without buffering
 	}
 };
 // Rate limiter
 class Rate {
 public:
@@ -105,23 +105,10 @@ public:
 	}
 	static Vector rotationVectorBetween(const Vector& a, const Vector& b) {
 		float an = a.norm();
 		float bn = b.norm();
 		if (an < 1e-6 || bn < 1e-6) {
 			return Vector(0, 0, 0);
 		}
 		Vector direction = cross(a, b);
-		if (direction.norm() < 1e-6) { // vectors are parallel
+		if (direction.zero()) {
-			if (dot(a, b) > 0) { // same direction
+			// vectors are opposite, return any perpendicular vector
-				return Vector(0, 0, 0);
+			return cross(a, Vector(1, 0, 0));
 			}
 			// opposite direction
 			Vector perp = cross(a, Vector(1, 0, 0));
 			if (perp.norm() < 1e-6) {
 				perp = cross(a, Vector(0, 1, 0));
 			}
 			perp.normalize();
 			return perp * PI;
 		}
 		direction.normalize();
 		float angle = angleBetween(a, b);
@@ -1,129 +1,76 @@
 // Copyright (c) 2023 Oleg Kalachev <okalachev@gmail.com>
 // Repository: https://github.com/okalachev/flix
-// Wi-Fi and ESP-NOW communication
+// Wi-Fi communication
 #include <WiFi.h>
 #include <WiFiAP.h>
 #include <WiFiUdp.h>
 #include <MacAddress.h>
 #include <ESP32_NOW_Serial.h>
 #include "Preferences.h"
 #include "util.h"
 extern Preferences storage; // use the main preferences storage
-const int W_DISABLED = 0, W_AP = 1, W_STA = 2, W_ESPNOW = 3;
+const int W_DISABLED = 0, W_AP = 1, W_STA = 2;
 int wifiMode = W_AP;
 int wifiLongRange = 0;
 int udpLocalPort = 14550;
 int udpRemotePort = 14550;
 IPAddress udpRemoteIP = "255.255.255.255";
 WiFiUDP udp;
-ESPNOWSerial espnow(NULL, 0, WIFI_IF_AP);
+WiFiUDP udp;
 ESPNOWSerial espnowBroadcast(ESP_NOW.BROADCAST_ADDR, 0, WIFI_IF_AP);
 int espnowChannel = 6;
 void setupWiFi() {
 	print("Setup Wi-Fi\n");
 	WiFi.enableLongRange(wifiLongRange);
 	if (wifiMode == W_AP) {
 		WiFi.softAP(storage.getString("WIFI_AP_SSID", "flix").c_str(), storage.getString("WIFI_AP_PASS", "flixwifi").c_str());
 		udp.begin(udpLocalPort);
 	} else if (wifiMode == W_STA) {
 		WiFi.begin(storage.getString("WIFI_STA_SSID", "").c_str(), storage.getString("WIFI_STA_PASS", "").c_str());
 		udp.begin(udpLocalPort);
 	} else if (wifiMode == W_ESPNOW) {
 		WiFi.mode(WIFI_AP);
 		WiFi.setChannel(espnowChannel);
 		espnow.addr(MacAddress(storage.getString("ESPNOW_PEER_MAC", "FF:FF:FF:FF:FF:FF").c_str()));
 		String key = storage.getString("ESPNOW_PEER_KEY", "");
 		espnow.setKey(key.isEmpty() ? nullptr : (const uint8_t *)key.c_str());
 		espnow.begin();
 		espnowBroadcast.begin();
 	}
-
+	udp.begin(udpLocalPort);
 	WiFi.setSleep(false); // disable power save
 }
 void sendWiFi(const uint8_t *buf, int len) {
 	if (espnow) {
 		espnow.write(buf, len);
 		static Rate discovery(2);
 		if (discovery) espnowBroadcast.write((const uint8_t *)"flix", 4); // broadcast message to help finding this device
 		return;
 	}
 	if (WiFi.softAPgetStationNum() == 0 && !WiFi.isConnected()) return;
 	udp.beginPacket(udpRemoteIP, udpRemotePort);
 	udp.write(buf, len);
 	udp.endPacket();
 }
 int receiveWiFi(uint8_t *buf, int len) {
 	if (espnow) {
 		return espnow.read(buf, len);
 	}
 	if (WiFi.softAPgetStationNum() == 0 && !WiFi.isConnected()) return 0;
 	udp.parsePacket();
 	if (udp.remoteIP()) udpRemoteIP = udp.remoteIP();
 	return udp.read(buf, len);
 }
 void printWiFiInfo() {
-	if (espnow) {
+	if (WiFi.getMode() == WIFI_MODE_AP) {
 		print("Mode: ESP-NOW\n");
 		print("ESP-NOW version: %d\n", ESP_NOW.getVersion());
 		print("Max packet size: %d\n", ESP_NOW.getMaxDataLen());
 		print("MAC: %s\n", WiFi.softAPmacAddress().c_str());
 		print("Peer MAC: %s\n", MacAddress(espnow.addr()).toString().c_str());
 		print("Encrypted: %d\n", espnow.isEncrypted());
 		print("Channel: %d\n", espnow.getChannel());
 	} else if (WiFi.getMode() == WIFI_MODE_AP) {
 		print("Mode: Access Point (AP)\n");
 		print("MAC: %s\n", WiFi.softAPmacAddress().c_str());
 		print("SSID: %s\n", WiFi.softAPSSID().c_str());
 		print("Password: ***\n");
 		print("Channel: %d\n", WiFi.channel());
 		print("Clients: %d\n", WiFi.softAPgetStationNum());
 		print("IP: %s\n", WiFi.softAPIP().toString().c_str());
 		print("Remote IP: %s\n", udpRemoteIP.toString().c_str());
 	} else if (WiFi.getMode() == WIFI_MODE_STA) {
 		print("Mode: Client (STA)\n");
 		print("Connected: %d\n", WiFi.isConnected());
 		print("MAC: %s\n", WiFi.macAddress().c_str());
 		print("SSID: %s\n", WiFi.SSID().c_str());
 		print("Password: ***\n");
 		print("Channel: %d\n", WiFi.channel());
 		print("RSSI: %d dBm\n", WiFi.RSSI());
 		print("IP: %s\n", WiFi.localIP().toString().c_str());
 		print("Remote IP: %s\n", udpRemoteIP.toString().c_str());
 	} else {
 		print("Mode: Disabled\n");
 		return;
 	}
 	print("Remote IP: %s\n", udpRemoteIP.toString().c_str());
 	print("MAVLink connected: %d\n", mavlinkConnected);
 }
-void configWiFi(int mode, const char *first, const char *second) {
+void configWiFi(bool ap, const char *ssid, const char *password) {
-	MacAddress mac;
+	if (ap) {
-	if (mode == W_AP && strlen(first) > 0 && strlen(second) >= 8) {
+		storage.putString("WIFI_AP_SSID", ssid);
-		storage.putString("WIFI_AP_SSID", first);
+		storage.putString("WIFI_AP_PASS", password);
 		storage.putString("WIFI_AP_PASS", second);
 	} else if (mode == W_STA && strlen(first) > 0 && strlen(second) >= 8) {
 		storage.putString("WIFI_STA_SSID", first);
 		storage.putString("WIFI_STA_PASS", second);
 	} else if (mode == W_ESPNOW && mac.fromString(first)) {
 		storage.putString("ESPNOW_PEER_MAC", first);
 		storage.putString("ESPNOW_PEER_KEY", strlen(second) == ESP_NOW_KEY_LEN ? second : "");
 	} else {
-		print("Invalid configuration\n");
+		storage.putString("WIFI_STA_SSID", ssid);
-		return;
+		storage.putString("WIFI_STA_PASS", password);
 	}
 	print("✓ Reboot to apply new settings\n");
 }
@@ -21,8 +21,6 @@
 #define degrees(rad) ((rad)*RAD_TO_DEG)
 #define constrain(amt,low,high) ((amt)<(low)?(low):((amt)>(high)?(high):(amt)))
 template<typename T> T max(T a, T b) { return a > b ? a : b; }
 template<typename T> T min(T a, T b) { return a < b ? a : b; }
 long map(long x, long in_min, long in_max, long out_min, long out_max) {
 	const long run = in_max - in_min;
@@ -151,7 +149,7 @@ public:
 	void setRxInvert(bool invert) {};
 };
-HardwareSerial Serial, Serial1, Serial2;
+HardwareSerial Serial, Serial2;
 class EspClass {
 public:
@@ -168,8 +166,6 @@ void delay(uint32_t ms) {
 bool ledcAttach(uint8_t pin, uint32_t freq, uint8_t resolution) { return true; }
 bool ledcWrite(uint8_t pin, uint32_t duty) { return true; }
 uint32_t ledcChangeFrequency(uint8_t pin, uint32_t freq, uint8_t resolution) { return freq; }
 int8_t digitalPinToAnalogChannel(uint8_t pin) { return -1; }
 uint32_t analogReadMilliVolts(uint8_t pin) { return 0; }
 unsigned long __micros;
 unsigned long __resetTime = 0;
@@ -1,12 +0,0 @@
 // Dummy file for the simulator
 class ESP_NOW_Peer {
 protected:
 	size_t send(const uint8_t *data, int len) { return 0; }
 };
 class ESP_NOW_Serial_Class : public ESP_NOW_Peer {
 public:
 	virtual void onSent(bool success) {};
 	virtual size_t write(const uint8_t *data, size_t len) { return 0; };
 };
@@ -13,7 +13,7 @@ class SBUS {
 public:
 	SBUS(HardwareSerial& bus, const bool inv = true) {};
 	SBUS(HardwareSerial& bus, const int8_t rxpin, const int8_t txpin, const bool inv = true) {};
-	void begin(int rxpin = -1, int txpin = -1, bool inv = true, bool fast = false) {};
+	void begin() {};
 	bool read() { return joystickInit(); };
 	SBUSData data() {
 		SBUSData data;
@@ -9,7 +9,6 @@
 #include "quaternion.h"
 #include "Arduino.h"
 #include "wifi.h"
 #include "lpf.h"
 extern float t, dt;
 extern float controlRoll, controlPitch, controlYaw, controlThrottle, controlMode;
@@ -20,20 +19,17 @@ extern float motors[4];
 Vector gyro, acc, imuRotation;
 Vector accBias, gyroBias, accScale(1, 1, 1);
 LowPassFilter<Vector> gyroBiasFilter(0);
 // declarations
 void step();
 void computeLoopRate();
 void applyGyro();
 void applyAcc();
 void applyLevel();
 void control();
 void interpretControls();
 void controlAttitude();
 void controlRates();
 void controlTorque();
 void desaturate(float& a, float& b, float& c, float& d);
 const char* getModeName();
 void sendMotors();
 int getDutyCycle(float value);
@@ -43,10 +39,9 @@ void print(const char* format, ...);
 void pause(float duration);
 void doCommand(String str, bool echo);
 void handleInput();
 void setupRC();
 void normalizeRC();
 void calibrateRC();
-void calibrateRCChannel(int*, uint16_t[16], uint16_t[16], const char*);
+void calibrateRCChannel(float *channel, uint16_t zero[16], uint16_t max[16], const char *str);
 void printRCCalibration();
 void printLogHeader();
 void printLogData();
@@ -58,7 +53,6 @@ void handleMavlink(const void *_msg);
 void mavlinkPrint(const char* str);
 void sendMavlinkPrint();
 inline Quaternion fluToFrd(const Quaternion &q);
 void setupPower();
 void failsafe();
 void rcLossFailsafe();
 void descend();
@@ -27,7 +27,6 @@
 #include "mavlink.ino"
 #include "motors.ino"
 #include "parameters.ino"
 #include "power.ino"
 #include "rc.ino"
 #include "time.ino"
@@ -73,8 +72,6 @@ public:
 		gyro = Vector(imu->AngularVelocity().X(), imu->AngularVelocity().Y(), imu->AngularVelocity().Z());
 		acc = this->accFilter.update(Vector(imu->LinearAcceleration().X(), imu->LinearAcceleration().Y(), imu->LinearAcceleration().Z()));
 		voltage = 4.2f; // dummy voltage value
 		readRC();
 		estimate();
@@ -1,3 +1,4 @@
 // Dummy file to make it possible to compile simulator with Flix' util.h
 #define WRITE_PERI_REG(addr, val) {}
 #define REG_CLR_BIT(_r, _b) {}
@@ -11,10 +11,9 @@
 #include <sys/poll.h>
 #include <gazebo/gazebo.hh>
-int wifiMode = 1; // mock
+#define WIFI_UDP_PORT 14580
-int udpLocalPort = 14580;
+#define WIFI_UDP_REMOTE_PORT 14550
-int udpRemotePort = 14550;
+#define WIFI_UDP_REMOTE_ADDR "255.255.255.255"
 const char *udpRemoteIP = "255.255.255.255";
 int wifiSocket;
@@ -23,22 +22,22 @@ void setupWiFi() {
 	sockaddr_in addr; // local address
 	addr.sin_family = AF_INET;
 	addr.sin_addr.s_addr = INADDR_ANY;
-	addr.sin_port = htons(udpLocalPort);
+	addr.sin_port = htons(WIFI_UDP_PORT);
 	if (bind(wifiSocket, (sockaddr *)&addr, sizeof(addr))) {
-		gzerr << "Failed to bind WiFi UDP socket on port " << udpLocalPort << std::endl;
+		gzerr << "Failed to bind WiFi UDP socket on port " << WIFI_UDP_PORT << std::endl;
 		return;
 	}
 	int broadcast = 1;
 	setsockopt(wifiSocket, SOL_SOCKET, SO_BROADCAST, &broadcast, sizeof(broadcast)); // enable broadcast
-	gzmsg << "WiFi UDP socket initialized on port " << udpLocalPort << " (remote port " << udpRemotePort << ")" << std::endl;
+	gzmsg << "WiFi UDP socket initialized on port " << WIFI_UDP_PORT << " (remote port " << WIFI_UDP_REMOTE_PORT << ")" << std::endl;
 }
 void sendWiFi(const uint8_t *buf, int len) {
 	if (wifiSocket == 0) setupWiFi();
 	sockaddr_in addr; // remote address
 	addr.sin_family = AF_INET;
-	addr.sin_addr.s_addr = inet_addr(udpRemoteIP);
+	addr.sin_addr.s_addr = inet_addr(WIFI_UDP_REMOTE_ADDR);
-	addr.sin_port = htons(udpRemotePort);
+	addr.sin_port = htons(WIFI_UDP_REMOTE_PORT);
 	sendto(wifiSocket, buf, len, 0, (sockaddr *)&addr, sizeof(addr));
 }
@@ -1,3 +0,0 @@
 # ESPNOW-proxy
 Proxy sketch for using ESP-NOW connection with Flix drone.
@@ -1,88 +0,0 @@
 // Copyright (c) 2026 Oleg Kalachev <okalachev@gmail.com>
 // Repository: https://github.com/okalachev/flix
 // Proxy for ESP-NOW connection
 #include <vector>
 #include <WiFi.h>
 #include <ESP32_NOW_Serial.h>
 #include <MacAddress.h>
 #include <MAVLink.h>
 #include <Preferences.h>
 #include "../../flix/util.h"
 const int CHANNEL = 6;
 char key[ESP_NOW_KEY_LEN + 1] = {0}; // with trailing null
 Preferences storage;
 std::vector<ESPNOWSerial *> peers;
 void onNewPeer(const esp_now_recv_info_t *info, const uint8_t *data, int len, void *arg) {
 	if (len != 4 || memcmp(data, "flix", 4) != 0) return; // check if discovery message
 	Serial.printf("New peer: " MACSTR "\n", MAC2STR(info->src_addr));
 	ESPNOWSerial *link = new ESPNOWSerial(info->src_addr, CHANNEL, WIFI_IF_AP);
 	link->begin();
 	link->setKey((const uint8_t *)key);
 	peers.push_back(link);
 }
 void setup() {
 	Serial.begin(115200);
 	WiFi.mode(WIFI_AP);
 	WiFi.setSleep(false);
 	WiFi.setChannel(CHANNEL);
 	ESP_NOW.onNewPeer(onNewPeer, NULL);
 	ESP_NOW.begin();
 	storage.begin("espnow-proxy");
 	if (!storage.isKey("key")) {
 		generateRandomKey();
 		storage.putString("key", key);
 	}
 	strcpy(key, storage.getString("key").c_str());
 	// Discover the first peer
 	while (peers.empty()) {
 		Serial.printf("espnow %s %s\n", WiFi.softAPmacAddress().c_str(), key);
 		delay(500);
 	}
 }
 void generateRandomKey() {
 	const char chars[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789!@#$%^&*-_+=";
 	for (int i = 0; i < ESP_NOW_KEY_LEN; i++) {
 		key[i] = chars[random(0, strlen(chars))];
 	}
 }
 void loop() {
 	uint8_t buf[5000];
 	// Send from Serial to ESP-NOW
 	while (Serial.available() > 0) {
 		int b = Serial.read();
 		if (b < 0) {
 			break;
 		}
 		mavlink_message_t msg;
 		mavlink_status_t status;
 		if (mavlink_parse_char(MAVLINK_COMM_0, (uint8_t)b, &msg, &status)) {
 			int len = mavlink_msg_to_send_buffer(buf, &msg);
 			for (ESPNOWSerial *link : peers) {
 				link->write(buf, len);
 			}
 		}
 	}
 	// Send from ESP-NOW to Serial
 	for (ESPNOWSerial *link : peers) {
 		int len = link->read(buf, sizeof(buf));
 		if (len > 0) {
 			Serial.write(buf, len);
 		}
 	}
 }
@@ -10,7 +10,6 @@ print('Connected:', flix.connected)
 print('Mode:', flix.mode)
 print('Armed:', flix.armed)
 print('Landed:', flix.landed)
 print('Voltage:', flix.voltage, 'V')
 print('Rates:', *[f'{math.degrees(r):.0f}°/s' for r in flix.rates])
 print('Attitude:', *[f'{math.degrees(a):.0f}°' for a in flix.attitude_euler])
 print('Motors:', flix.motors)
@@ -24,11 +23,11 @@ print('> imu')
 print(flix.cli('imu'))
 print('=== Get parameter...')
-pitch_p = flix.get_param('CTL_P_P')
+pitch_p = flix.get_param('PITCH_P')
-print('CTL_P_P = ', pitch_p)
+print('PITCH_P = ', pitch_p)
 print('=== Set parameter...')
-flix.set_param('CTL_P_P', pitch_p)
+flix.set_param('PITCH_P', pitch_p)
 print('=== Wait for gyro update...')
 print('Gyro: ', flix.wait('gyro'))
@@ -24,20 +24,19 @@ pip install pyflix
 The API is accessed through the `Flix` class:
 ```python
-from pyflix import Flix
+from flix import Flix
 flix = Flix()  # create a Flix object and wait for connection
 ```
 ### Telemetry
-Basic telemetry is available through object properties. The property names generally match the corresponding variables in the firmware code:
+Basic telemetry is available through object properties. The property names generally match the corresponding variables in the firmware itself:
 ```python
 print(flix.connected)       # True if connected to the drone
 print(flix.mode)            # current flight mode (str)
 print(flix.armed)           # True if the drone is armed
 print(flix.landed)          # True if the drone is landed
 print(flix.voltage)         # battery voltage (NaN - unknown, ~0 - USB powered)
 print(flix.attitude)        # attitude quaternion [w, x, y, z]
 print(flix.attitude_euler)  # attitude as Euler angles [roll, pitch, yaw]
 print(flix.rates)           # angular rates [roll_rate, pitch_rate, yaw_rate]
@@ -96,7 +95,6 @@ Full list of events:
 |`armed`|Armed state update|Armed state *(bool)*|
 |`mode`|Flight mode update|Flight mode *(str)*|
 |`landed`|Landed state update|Landed state *(bool)*|
 |`voltage`|Battery voltage update|Voltage *(float)*|
 |`print`|The drone prints text to the console|Text|
 |`attitude`|Attitude update|Attitude quaternion *(list)*|
 |`attitude_euler`|Attitude update|Euler angles *(list)*|
@@ -119,8 +117,8 @@ Full list of events:
 Get and set firmware parameters using `get_param` and `set_param` methods:
 ```python
-pitch_p = flix.get_param('CTL_P_P')  # get parameter value
+pitch_p = flix.get_param('PITCH_P')  # get parameter value
-flix.set_param('CTL_P_P', 5)         # set parameter value
+flix.set_param('PITCH_P', 5)         # set parameter value
 ```
 Execute console commands using `cli` method. This method returns the command response:
@@ -5,7 +5,6 @@
 import os
 import time
 import math
 from queue import Queue, Empty
 from typing import Optional, Callable, List, Dict, Any, Union, Sequence
 import logging
@@ -27,7 +26,6 @@ class Flix:
    mode: str = ''
    armed: bool = False
    landed: bool = False
    voltage: float = math.nan
    attitude: List[float]
    attitude_euler: List[float]  # roll, pitch, yaw
    rates: List[float]
@@ -70,7 +68,7 @@ class Flix:
        self._heartbeat_thread.start()
        if wait_connection:
            self.wait('mavlink.HEARTBEAT')
-            time.sleep(0.6) # give some time to receive initial state
+            time.sleep(0.2) # give some time to receive initial state
    def _init_state(self):
        self.attitude = [1, 0, 0, 0]
@@ -140,7 +138,7 @@ class Flix:
        while True:
            try:
                msg: Optional[mavlink.MAVLink_message] = self.connection.recv_match(blocking=True)
-                if msg is None or msg.get_srcSystem() != self.system_id:
+                if msg is None:
                    continue
                self._connected()
                msg_dict = msg.to_dict()
@@ -187,16 +185,11 @@ class Flix:
            self._trigger('motors', self.motors)
        if isinstance(msg, mavlink.MAVLink_scaled_imu_message):
-            ONE_G = 9.80665
+            self.acc = self._mavlink_to_flu([msg.xacc / 1000, msg.yacc / 1000, msg.zacc / 1000])
            self.acc = self._mavlink_to_flu([msg.xacc * ONE_G / 1000, msg.yacc * ONE_G / 1000, msg.zacc * ONE_G / 1000])
            self.gyro = self._mavlink_to_flu([msg.xgyro / 1000, msg.ygyro / 1000, msg.zgyro / 1000])
            self._trigger('acc', self.acc)
            self._trigger('gyro', self.gyro)
        if isinstance(msg, mavlink.MAVLink_battery_status_message):
            self.voltage = msg.voltages[0] / 1000
            self._trigger('voltage', self.voltage)
        if isinstance(msg, mavlink.MAVLink_serial_control_message):
            # new chunk of data
            text = bytes(msg.data)[:msg.count].decode('utf-8', errors='ignore')
@@ -1,6 +1,6 @@
 [project]
 name = "pyflix"
-version = "0.15"
+version = "0.11"
 description = "Python API for Flix drone"
 authors = [{ name="Oleg Kalachev", email="okalachev@gmail.com" }]
 license = "MIT"
		`@@ -1,3 +0,0 @@`
			`# ESPNOW-proxy`

			`Proxy sketch for using ESP-NOW connection with Flix drone.`