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    Max30102,MPU6050 and Esp8266

    ESP32
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    • A
      Adithya SM last edited by

      I am having some trouble connecting both the MAX30102 and MPU6050 sensors to my ESP8266 board. Both sensors use the I2C communication protocol to interface with the microcontroller.

      I have tried writing some baremetal code to read data from both sensors, but I am not getting any output values from either of them. I have also checked my wiring connections and confirmed that the sensors are receiving power.

      I would really appreciate any suggestions or advice on how to troubleshoot and resolve this issue. Specifically, I would like to know if there are any common issues that arise when using I2C communication with multiple sensors on an ESP8266 board. Additionally, if anyone has successfully interfaced these sensors with an ESP8266 board and can share their code or any tips, it would be greatly appreciated.

      salmanfaris 1 Reply Last reply Reply Quote 0
      • saheen_palayi
        saheen_palayi last edited by

        Hey @Adithya-SM
        Could you drop your code here?

        1 Reply Last reply Reply Quote 1
        • salmanfaris
          salmanfaris @Adithya SM last edited by

          @Adithya-SM Can you confirm the I2C address is correct? You can use this I2C Scanner to program to find the correct address

          
// --------------------------------------
// i2c_scanner
//
// Modified from https://playground.arduino.cc/Main/I2cScanner/
// --------------------------------------

#include <Wire.h>

// Set I2C bus to use: Wire, Wire1, etc.
#define WIRE Wire

void setup() {
  WIRE.begin();

  Serial.begin(9600);
  while (!Serial)
     delay(10);
  Serial.println("\nI2C Scanner");
}


void loop() {
  byte error, address;
  int nDevices;

  Serial.println("Scanning...");

  nDevices = 0;
  for(address = 1; address < 127; address++ ) 
  {
    // The i2c_scanner uses the return value of
    // the Write.endTransmisstion to see if
    // a device did acknowledge to the address.
    WIRE.beginTransmission(address);
    error = WIRE.endTransmission();

    if (error == 0)
    {
      Serial.print("I2C device found at address 0x");
      if (address<16) 
        Serial.print("0");
      Serial.print(address,HEX);
      Serial.println("  !");

      nDevices++;
    }
    else if (error==4) 
    {
      Serial.print("Unknown error at address 0x");
      if (address<16) 
        Serial.print("0");
      Serial.println(address,HEX);
    }    
  }
  if (nDevices == 0)
    Serial.println("No I2C devices found\n");
  else
    Serial.println("done\n");

  delay(5000);           // wait 5 seconds for next scan
}
          1 Reply Last reply Reply Quote 0
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          Recent Posts

          • Hi @PumpedMedusa, The rage is depends on the Antenna and how much TX power you have.

            To choose antenna, first you need figure out - where your nodes will be, take a look at the below image. The antenna act like a "torch" if you have more dbi that mean it's focus will be increase and it can reach more distance but the angle it have it less, like a laser.

            458a3da2-175a-4968-917c-56c5a1b763f8-image.png

            also, obstacle such as buildings, tress and mountains will affect the signal and deplete it.

            afe5eba4-b192-4263-8596-80c912fc1f23-image.png

            So, answer for you question - What is the best LoRa module to use for long distance network? - It's really depends on where you planning to put the nodes and how high you putting the gateway. Let me know know your thoughts.

            • read more

          • @Parves-DOMINO Did you able to solve the issue?

            • read more

          • @Parves-DOMINO Are you still facing the issue?

            • read more
          • P

            I am working on an object detection since 2 weeks. I have started the project by a testing object using edge impulse to create the library based on this object but when i compile the code i have an error
            That's the code

            #include <Parvesdomino-project-IPT_inferencing.h> #include "edge-impulse-sdk/dsp/image/image.hpp" #include "esp_camera.h" // Select camera model - find more camera models in camera_pins.h file here // https://github.com/espressif/arduino-esp32/blob/master/libraries/ESP32/examples/Camera/CameraWebServer/camera_pins.h //#define CAMERA_MODEL_ESP_EYE // Has PSRAM #define CAMERA_MODEL_AI_THINKER // Has PSRAM #if defined(CAMERA_MODEL_ESP_EYE) #define PWDN_GPIO_NUM -1 #define RESET_GPIO_NUM -1 #define XCLK_GPIO_NUM 4 #define SIOD_GPIO_NUM 18 #define SIOC_GPIO_NUM 23 #define Y9_GPIO_NUM 36 #define Y8_GPIO_NUM 37 #define Y7_GPIO_NUM 38 #define Y6_GPIO_NUM 39 #define Y5_GPIO_NUM 35 #define Y4_GPIO_NUM 14 #define Y3_GPIO_NUM 13 #define Y2_GPIO_NUM 34 #define VSYNC_GPIO_NUM 5 #define HREF_GPIO_NUM 27 #define PCLK_GPIO_NUM 25 #elif defined(CAMERA_MODEL_AI_THINKER) #define PWDN_GPIO_NUM 32 #define RESET_GPIO_NUM -1 #define XCLK_GPIO_NUM 0 #define SIOD_GPIO_NUM 26 #define SIOC_GPIO_NUM 27 #define Y9_GPIO_NUM 35 #define Y8_GPIO_NUM 34 #define Y7_GPIO_NUM 39 #define Y6_GPIO_NUM 36 #define Y5_GPIO_NUM 21 #define Y4_GPIO_NUM 19 #define Y3_GPIO_NUM 18 #define Y2_GPIO_NUM 5 #define VSYNC_GPIO_NUM 25 #define HREF_GPIO_NUM 23 #define PCLK_GPIO_NUM 22 #else #error "Camera model not selected" #endif /* Constant defines -------------------------------------------------------- */ #define EI_CAMERA_RAW_FRAME_BUFFER_COLS 320 #define EI_CAMERA_RAW_FRAME_BUFFER_ROWS 240 #define EI_CAMERA_FRAME_BYTE_SIZE 3 /* Private variables ------------------------------------------------------- */ static bool debug_nn = false; // Set this to true to see e.g. features generated from the raw signal static bool is_initialised = false; uint8_t *snapshot_buf; //points to the output of the capture static camera_config_t camera_config = { .pin_pwdn = PWDN_GPIO_NUM, .pin_reset = RESET_GPIO_NUM, .pin_xclk = XCLK_GPIO_NUM, .pin_sscb_sda = SIOD_GPIO_NUM, .pin_sscb_scl = SIOC_GPIO_NUM, .pin_d7 = Y9_GPIO_NUM, .pin_d6 = Y8_GPIO_NUM, .pin_d5 = Y7_GPIO_NUM, .pin_d4 = Y6_GPIO_NUM, .pin_d3 = Y5_GPIO_NUM, .pin_d2 = Y4_GPIO_NUM, .pin_d1 = Y3_GPIO_NUM, .pin_d0 = Y2_GPIO_NUM, .pin_vsync = VSYNC_GPIO_NUM, .pin_href = HREF_GPIO_NUM, .pin_pclk = PCLK_GPIO_NUM, //XCLK 20MHz or 10MHz for OV2640 double FPS (Experimental) .xclk_freq_hz = 20000000, .ledc_timer = LEDC_TIMER_0, .ledc_channel = LEDC_CHANNEL_0, .pixel_format = PIXFORMAT_JPEG, //YUV422,GRAYSCALE,RGB565,JPEG .frame_size = FRAMESIZE_QVGA, //QQVGA-UXGA Do not use sizes above QVGA when not JPEG .jpeg_quality = 12, //0-63 lower number means higher quality .fb_count = 1, //if more than one, i2s runs in continuous mode. Use only with JPEG .fb_location = CAMERA_FB_IN_PSRAM, .grab_mode = CAMERA_GRAB_WHEN_EMPTY, }; /* Function definitions ------------------------------------------------------- */ bool ei_camera_init(void); void ei_camera_deinit(void); bool ei_camera_capture(uint32_t img_width, uint32_t img_height, uint8_t *out_buf) ; /** * @brief Arduino setup function */ void setup() { // put your setup code here, to run once: Serial.begin(115200); //comment out the below line to start inference immediately after upload while (!Serial); Serial.println("Edge Impulse Inferencing Demo"); if (ei_camera_init() == false) { ei_printf("Failed to initialize Camera!\r\n"); } else { ei_printf("Camera initialized\r\n"); } ei_printf("\nStarting continious inference in 2 seconds...\n"); ei_sleep(2000); } /** * @brief Get data and run inferencing * * @param[in] debug Get debug info if true */ void loop() { // instead of wait_ms, we'll wait on the signal, this allows threads to cancel us... if (ei_sleep(5) != EI_IMPULSE_OK) { return; } snapshot_buf = (uint8_t*)malloc(EI_CAMERA_RAW_FRAME_BUFFER_COLS * EI_CAMERA_RAW_FRAME_BUFFER_ROWS * EI_CAMERA_FRAME_BYTE_SIZE); // check if allocation was successful if(snapshot_buf == nullptr) { ei_printf("ERR: Failed to allocate snapshot buffer!\n"); return; } ei::signal_t signal; signal.total_length = EI_CLASSIFIER_INPUT_WIDTH * EI_CLASSIFIER_INPUT_HEIGHT; signal.get_data = &ei_camera_get_data; if (ei_camera_capture((size_t)EI_CLASSIFIER_INPUT_WIDTH, (size_t)EI_CLASSIFIER_INPUT_HEIGHT, snapshot_buf) == false) { ei_printf("Failed to capture image\r\n"); free(snapshot_buf); return; } // Run the classifier ei_impulse_result_t result = { 0 }; EI_IMPULSE_ERROR err = run_classifier(&signal, &result, debug_nn); if (err != EI_IMPULSE_OK) { ei_printf("ERR: Failed to run classifier (%d)\n", err); return; } // print the predictions ei_printf("Predictions (DSP: %d ms., Classification: %d ms., Anomaly: %d ms.): \n", result.timing.dsp, result.timing.classification, result.timing.anomaly); #if EI_CLASSIFIER_OBJECT_DETECTION == 1 ei_printf("Object detection bounding boxes:\r\n"); for (uint32_t i = 0; i < result.bounding_boxes_count; i++) { ei_impulse_result_bounding_box_t bb = result.bounding_boxes[i]; if (bb.value == 0) { continue; } ei_printf(" %s (%f) [ x: %u, y: %u, width: %u, height: %u ]\r\n", bb.label, bb.value, bb.x, bb.y, bb.width, bb.height); } // Print the prediction results (classification) #else ei_printf("Predictions:\r\n"); for (uint16_t i = 0; i < EI_CLASSIFIER_LABEL_COUNT; i++) { ei_printf(" %s: ", ei_classifier_inferencing_categories[i]); ei_printf("%.5f\r\n", result.classification[i].value); } #endif // Print anomaly result (if it exists) #if EI_CLASSIFIER_HAS_ANOMALY ei_printf("Anomaly prediction: %.3f\r\n", result.anomaly); #endif #if EI_CLASSIFIER_HAS_VISUAL_ANOMALY ei_printf("Visual anomalies:\r\n"); for (uint32_t i = 0; i < result.visual_ad_count; i++) { ei_impulse_result_bounding_box_t bb = result.visual_ad_grid_cells[i]; if (bb.value == 0) { continue; } ei_printf(" %s (%f) [ x: %u, y: %u, width: %u, height: %u ]\r\n", bb.label, bb.value, bb.x, bb.y, bb.width, bb.height); } #endif free(snapshot_buf); } /** * @brief Setup image sensor & start streaming * * @retval false if initialisation failed */ bool ei_camera_init(void) { if (is_initialised) return true; #if defined(CAMERA_MODEL_ESP_EYE) pinMode(13, INPUT_PULLUP); pinMode(14, INPUT_PULLUP); #endif //initialize the camera esp_err_t err = esp_camera_init(&camera_config); if (err != ESP_OK) { Serial.printf("Camera init failed with error 0x%x\n", err); return false; } // sensor_t * s = esp_camera_sensor_get(); // initial sensors are flipped vertically and colors are a bit saturated //if (s->id.PID == OV3660_PID) { // s->set_vflip(s, 1); // flip it back // s->set_brightness(s, 1); // up the brightness just a bit // s->set_saturation(s, 0); // lower the saturation } #if defined(CAMERA_MODEL_M5STACK_WIDE) s->set_vflip(s, 1); s->set_hmirror(s, 1); #elif defined(CAMERA_MODEL_ESP_EYE) s->set_vflip(s, 1); s->set_hmirror(s, 1); s->set_awb_gain(s, 1); #endif is_initialised = true; return true; } /** * @brief Stop streaming of sensor data */ void ei_camera_deinit(void) { //deinitialize the camera esp_err_t err = esp_camera_deinit(); if (err != ESP_OK) { ei_printf("Camera deinit failed\n"); return; } is_initialised = false; return; } /** * @brief Capture, rescale and crop image * * @param[in] img_width width of output image * @param[in] img_height height of output image * @param[in] out_buf pointer to store output image, NULL may be used * if ei_camera_frame_buffer is to be used for capture and resize/cropping. * * @retval false if not initialised, image captured, rescaled or cropped failed * */ bool ei_camera_capture(uint32_t img_width, uint32_t img_height, uint8_t *out_buf) { bool do_resize = false; if (!is_initialised) { ei_printf("ERR: Camera is not initialized\r\n"); return false; } camera_fb_t *fb = esp_camera_fb_get(); if (!fb) { ei_printf("Camera capture failed\n"); return false; } bool converted = fmt2rgb888(fb->buf, fb->len, PIXFORMAT_JPEG, snapshot_buf); esp_camera_fb_return(fb); if(!converted){ ei_printf("Conversion failed\n"); return false; } if ((img_width != EI_CAMERA_RAW_FRAME_BUFFER_COLS) || (img_height != EI_CAMERA_RAW_FRAME_BUFFER_ROWS)) { do_resize = true; } if (do_resize) { ei::image::processing::crop_and_interpolate_rgb888( out_buf, EI_CAMERA_RAW_FRAME_BUFFER_COLS, EI_CAMERA_RAW_FRAME_BUFFER_ROWS, out_buf, img_width, img_height); } return true; } static int ei_camera_get_data(size_t offset, size_t length, float *out_ptr) { // we already have a RGB888 buffer, so recalculate offset into pixel index size_t pixel_ix = offset * 3; size_t pixels_left = length; size_t out_ptr_ix = 0; while (pixels_left != 0) { // Swap BGR to RGB here // due to https://github.com/espressif/esp32-camera/issues/379 out_ptr[out_ptr_ix] = (snapshot_buf[pixel_ix + 2] << 16) + (snapshot_buf[pixel_ix + 1] << 8) + snapshot_buf[pixel_ix]; // go to the next pixel out_ptr_ix++; pixel_ix+=3; pixels_left--; } // and done! return 0; } #if !defined(EI_CLASSIFIER_SENSOR) || EI_CLASSIFIER_SENSOR != EI_CLASSIFIER_SENSOR_CAMERA #error "Invalid model for current sensor" #endif

            And here is the error:

            C:\Users\HP\AppData\Local\Temp\.arduinoIDE-unsaved202486-9240-1p71wzh.ggfb\esp32_camera\esp32_camera.ino:382:2: error: #error "Invalid model for current sensor" 382 | #error "Invalid model for current sensor" | ^~~~~ exit status 1 Compilation error: #error "Invalid model for current sensor"

            Please help me to solve this.

            • read more
          • P

            I am working on an object detection since 2 weeks. I have started the project by a testing object using edge impulse to create the library based on this object but when i compile the code i have an error
            That's the code:

            '''
            #include <Parvesdomino-project-IPT_inferencing.h>
            #include "edge-impulse-sdk/dsp/image/image.hpp"

            #include "esp_camera.h"

            // Select camera model - find more camera models in camera_pins.h file here
            // https://github.com/espressif/arduino-esp32/blob/master/libraries/ESP32/examples/Camera/CameraWebServer/camera_pins.h

            //#define CAMERA_MODEL_ESP_EYE // Has PSRAM
            #define CAMERA_MODEL_AI_THINKER // Has PSRAM

            #if defined(CAMERA_MODEL_ESP_EYE)
            #define PWDN_GPIO_NUM -1
            #define RESET_GPIO_NUM -1
            #define XCLK_GPIO_NUM 4
            #define SIOD_GPIO_NUM 18
            #define SIOC_GPIO_NUM 23

            #define Y9_GPIO_NUM 36
            #define Y8_GPIO_NUM 37
            #define Y7_GPIO_NUM 38
            #define Y6_GPIO_NUM 39
            #define Y5_GPIO_NUM 35
            #define Y4_GPIO_NUM 14
            #define Y3_GPIO_NUM 13
            #define Y2_GPIO_NUM 34
            #define VSYNC_GPIO_NUM 5
            #define HREF_GPIO_NUM 27
            #define PCLK_GPIO_NUM 25

            #elif defined(CAMERA_MODEL_AI_THINKER)
            #define PWDN_GPIO_NUM 32
            #define RESET_GPIO_NUM -1
            #define XCLK_GPIO_NUM 0
            #define SIOD_GPIO_NUM 26
            #define SIOC_GPIO_NUM 27

            #define Y9_GPIO_NUM 35
            #define Y8_GPIO_NUM 34
            #define Y7_GPIO_NUM 39
            #define Y6_GPIO_NUM 36
            #define Y5_GPIO_NUM 21
            #define Y4_GPIO_NUM 19
            #define Y3_GPIO_NUM 18
            #define Y2_GPIO_NUM 5
            #define VSYNC_GPIO_NUM 25
            #define HREF_GPIO_NUM 23
            #define PCLK_GPIO_NUM 22

            #else
            #error "Camera model not selected"
            #endif

            /* Constant defines -------------------------------------------------------- */
            #define EI_CAMERA_RAW_FRAME_BUFFER_COLS 320
            #define EI_CAMERA_RAW_FRAME_BUFFER_ROWS 240
            #define EI_CAMERA_FRAME_BYTE_SIZE 3

            /* Private variables ------------------------------------------------------- */
            static bool debug_nn = false; // Set this to true to see e.g. features generated from the raw signal
            static bool is_initialised = false;
            uint8_t *snapshot_buf; //points to the output of the capture

            static camera_config_t camera_config = {
            .pin_pwdn = PWDN_GPIO_NUM,
            .pin_reset = RESET_GPIO_NUM,
            .pin_xclk = XCLK_GPIO_NUM,
            .pin_sscb_sda = SIOD_GPIO_NUM,
            .pin_sscb_scl = SIOC_GPIO_NUM,

            .pin_d7 = Y9_GPIO_NUM, .pin_d6 = Y8_GPIO_NUM, .pin_d5 = Y7_GPIO_NUM, .pin_d4 = Y6_GPIO_NUM, .pin_d3 = Y5_GPIO_NUM, .pin_d2 = Y4_GPIO_NUM, .pin_d1 = Y3_GPIO_NUM, .pin_d0 = Y2_GPIO_NUM, .pin_vsync = VSYNC_GPIO_NUM, .pin_href = HREF_GPIO_NUM, .pin_pclk = PCLK_GPIO_NUM, //XCLK 20MHz or 10MHz for OV2640 double FPS (Experimental) .xclk_freq_hz = 20000000, .ledc_timer = LEDC_TIMER_0, .ledc_channel = LEDC_CHANNEL_0, .pixel_format = PIXFORMAT_JPEG, //YUV422,GRAYSCALE,RGB565,JPEG .frame_size = FRAMESIZE_QVGA, //QQVGA-UXGA Do not use sizes above QVGA when not JPEG .jpeg_quality = 12, //0-63 lower number means higher quality .fb_count = 1, //if more than one, i2s runs in continuous mode. Use only with JPEG .fb_location = CAMERA_FB_IN_PSRAM, .grab_mode = CAMERA_GRAB_WHEN_EMPTY,

            };

            /* Function definitions ------------------------------------------------------- */
            bool ei_camera_init(void);
            void ei_camera_deinit(void);
            bool ei_camera_capture(uint32_t img_width, uint32_t img_height, uint8_t *out_buf) ;

            /**

            @brief Arduino setup function
            */
            void setup()
            {
            // put your setup code here, to run once:
            Serial.begin(115200);
            //comment out the below line to start inference immediately after upload
            while (!Serial);
            Serial.println("Edge Impulse Inferencing Demo");
            if (ei_camera_init() == false) {
            ei_printf("Failed to initialize Camera!\r\n");
            }
            else {
            ei_printf("Camera initialized\r\n");
            }

            ei_printf("\nStarting continious inference in 2 seconds...\n");
            ei_sleep(2000);
            }

            /**

            @brief Get data and run inferencing

            @param[in] debug Get debug info if true
            */
            void loop()
            {

            // instead of wait_ms, we'll wait on the signal, this allows threads to cancel us...
            if (ei_sleep(5) != EI_IMPULSE_OK) {
            return;
            }

            snapshot_buf = (uint8_t*)malloc(EI_CAMERA_RAW_FRAME_BUFFER_COLS * EI_CAMERA_RAW_FRAME_BUFFER_ROWS * EI_CAMERA_FRAME_BYTE_SIZE);

            // check if allocation was successful
            if(snapshot_buf == nullptr) {
            ei_printf("ERR: Failed to allocate snapshot buffer!\n");
            return;
            }

            ei::signal_t signal;
            signal.total_length = EI_CLASSIFIER_INPUT_WIDTH * EI_CLASSIFIER_INPUT_HEIGHT;
            signal.get_data = &ei_camera_get_data;

            if (ei_camera_capture((size_t)EI_CLASSIFIER_INPUT_WIDTH, (size_t)EI_CLASSIFIER_INPUT_HEIGHT, snapshot_buf) == false) {
            ei_printf("Failed to capture image\r\n");
            free(snapshot_buf);
            return;
            }

            // Run the classifier
            ei_impulse_result_t result = { 0 };

            EI_IMPULSE_ERROR err = run_classifier(&signal, &result, debug_nn);
            if (err != EI_IMPULSE_OK) {
            ei_printf("ERR: Failed to run classifier (%d)\n", err);
            return;
            }

            // print the predictions
            ei_printf("Predictions (DSP: %d ms., Classification: %d ms., Anomaly: %d ms.): \n",
            result.timing.dsp, result.timing.classification, result.timing.anomaly);

            #if EI_CLASSIFIER_OBJECT_DETECTION == 1
            ei_printf("Object detection bounding boxes:\r\n");
            for (uint32_t i = 0; i < result.bounding_boxes_count; i++) {
            ei_impulse_result_bounding_box_t bb = result.bounding_boxes[i];
            if (bb.value == 0) {
            continue;
            }
            ei_printf(" %s (%f) [ x: %u, y: %u, width: %u, height: %u ]\r\n",
            bb.label,
            bb.value,
            bb.x,
            bb.y,
            bb.width,
            bb.height);
            }

            // Print the prediction results (classification)

            #else
            ei_printf("Predictions:\r\n");
            for (uint16_t i = 0; i < EI_CLASSIFIER_LABEL_COUNT; i++) {
            ei_printf(" %s: ", ei_classifier_inferencing_categories[i]);
            ei_printf("%.5f\r\n", result.classification[i].value);
            }
            #endif

            // Print anomaly result (if it exists)

            #if EI_CLASSIFIER_HAS_ANOMALY
            ei_printf("Anomaly prediction: %.3f\r\n", result.anomaly);
            #endif

            #if EI_CLASSIFIER_HAS_VISUAL_ANOMALY
            ei_printf("Visual anomalies:\r\n");
            for (uint32_t i = 0; i < result.visual_ad_count; i++) {
            ei_impulse_result_bounding_box_t bb = result.visual_ad_grid_cells[i];
            if (bb.value == 0) {
            continue;
            }
            ei_printf(" %s (%f) [ x: %u, y: %u, width: %u, height: %u ]\r\n",
            bb.label,
            bb.value,
            bb.x,
            bb.y,
            bb.width,
            bb.height);
            }
            #endif

            free(snapshot_buf);

            }

            /**

            @brief Setup image sensor & start streaming

            @retval false if initialisation failed
            */
            bool ei_camera_init(void) {

            if (is_initialised) return true;

            #if defined(CAMERA_MODEL_ESP_EYE)
            pinMode(13, INPUT_PULLUP);
            pinMode(14, INPUT_PULLUP);
            #endif

            //initialize the camera esp_err_t err = esp_camera_init(&camera_config); if (err != ESP_OK) { Serial.printf("Camera init failed with error 0x%x\n", err); return false; }

            // sensor_t * s = esp_camera_sensor_get();
            // initial sensors are flipped vertically and colors are a bit saturated
            //if (s->id.PID == OV3660_PID) {
            // s->set_vflip(s, 1); // flip it back
            // s->set_brightness(s, 1); // up the brightness just a bit
            // s->set_saturation(s, 0); // lower the saturation
            }

            #if defined(CAMERA_MODEL_M5STACK_WIDE)
            s->set_vflip(s, 1);
            s->set_hmirror(s, 1);
            #elif defined(CAMERA_MODEL_ESP_EYE)
            s->set_vflip(s, 1);
            s->set_hmirror(s, 1);
            s->set_awb_gain(s, 1);
            #endif

            is_initialised = true; return true;

            }

            /**

            @brief Stop streaming of sensor data
            */
            void ei_camera_deinit(void) {

            //deinitialize the camera
            esp_err_t err = esp_camera_deinit();

            if (err != ESP_OK)
            {
            ei_printf("Camera deinit failed\n");
            return;
            }

            is_initialised = false;
            return;
            }

            /**

            @brief Capture, rescale and crop image @param[in] img_width width of output image @param[in] img_height height of output image @param[in] out_buf pointer to store output image, NULL may be used if ei_camera_frame_buffer is to be used for capture and resize/cropping. @retval false if not initialised, image captured, rescaled or cropped failed

            */
            bool ei_camera_capture(uint32_t img_width, uint32_t img_height, uint8_t *out_buf) {
            bool do_resize = false;

            if (!is_initialised) { ei_printf("ERR: Camera is not initialized\r\n"); return false; } camera_fb_t *fb = esp_camera_fb_get(); if (!fb) { ei_printf("Camera capture failed\n"); return false; }

            bool converted = fmt2rgb888(fb->buf, fb->len, PIXFORMAT_JPEG, snapshot_buf);

            esp_camera_fb_return(fb);

            if(!converted){
            ei_printf("Conversion failed\n");
            return false;
            }

            if ((img_width != EI_CAMERA_RAW_FRAME_BUFFER_COLS) || (img_height != EI_CAMERA_RAW_FRAME_BUFFER_ROWS)) { do_resize = true; } if (do_resize) { ei::image::processing::crop_and_interpolate_rgb888( out_buf, EI_CAMERA_RAW_FRAME_BUFFER_COLS, EI_CAMERA_RAW_FRAME_BUFFER_ROWS, out_buf, img_width, img_height); } return true;

            }

            static int ei_camera_get_data(size_t offset, size_t length, float *out_ptr)
            {
            // we already have a RGB888 buffer, so recalculate offset into pixel index
            size_t pixel_ix = offset * 3;
            size_t pixels_left = length;
            size_t out_ptr_ix = 0;

            while (pixels_left != 0) { // Swap BGR to RGB here // due to https://github.com/espressif/esp32-camera/issues/379 out_ptr[out_ptr_ix] = (snapshot_buf[pixel_ix + 2] << 16) + (snapshot_buf[pixel_ix + 1] << 8) + snapshot_buf[pixel_ix]; // go to the next pixel out_ptr_ix++; pixel_ix+=3; pixels_left--; } // and done! return 0;

            }

            #if !defined(EI_CLASSIFIER_SENSOR) || EI_CLASSIFIER_SENSOR != EI_CLASSIFIER_SENSOR_CAMERA
            #error "Invalid model for current sensor"
            #endif
            '''

            and here is the error
            '''
            C:\Users\HP\AppData\Local\Temp.arduinoIDE-unsaved202486-9240-1p71wzh.ggfb\esp32_camera\esp32_camera.ino:382:2: error: #error "Invalid model for current sensor"
            382 | #error "Invalid model for current sensor"
            | ^~~~~
            exit status 1

            Compilation error: #error "Invalid model for current sensor"
            '''

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