Compare commits

..

No commits in common. "1a54d4bc59eb0bd38bba0f9fc673129e9a97d299" and "100650edb21f2788f03ce85b8644dc14462f6280" have entirely different histories.

6 changed files with 263 additions and 361 deletions

View file

@ -1,39 +1,36 @@
/* Add https://dl.espressif.com/dl/package_esp32_index.json to your arduino IDE to get ESP32 support
*/
#include <Arduino.h>
#include <driver/i2s.h>
#include <driver/adc.h>
#include <soc/syscon_reg.h>
#include <TFT_eSPI.h>
#include <SPI.h>
#include "esp_adc_cal.h"
#include "filters.h"
//#define DEBUG_SERIAL
#define DEBUG_BUFF
#define DEBUG_DELAY 250
//#define DEBUG_BUFF
#define DELAY 1000
// Width and height of sprite
#define DISPLAY_HEIGHT 240
#define DISPLAY_WIDTH 320
#define WIDTH 240
#define HEIGHT 280
#define ADC_CHANNEL ADC1_CHANNEL_5 // GPIO33
#define NUM_SAMPLES 1000 // number of samples
#define I2S_NUM (0)
#define BUFF_SIZE 50000
#define B_MULT BUFF_SIZE/NUM_SAMPLES
#define BUTTON_Ok 32
#define BUTTON_Plus 15
#define BUTTON_Minus 35
#define BUTTON_Back 34
TFT_eSPI tft = TFT_eSPI(); // Declare object "tft"
TFT_eSprite spr = TFT_eSprite(&tft); // Declare Sprite object "spr" with pointer to "tft" object
esp_adc_cal_characteristics_t adc_chars;
TaskHandle_t task_menu;
@ -167,7 +164,7 @@ void core0_task( void * pvParameters ) {
update_screen(i2s_buff, RATE);
updating_screen = false;
vTaskDelay(pdMS_TO_TICKS(10));
//Serial.println("CORE0");
Serial.println("CORE0");
}
vTaskDelay(pdMS_TO_TICKS(10));
@ -175,90 +172,75 @@ void core0_task( void * pvParameters ) {
}
void core1_task(void *pvParameters)
{
void core1_task( void * pvParameters ) {
(void)pvParameters;
(void) pvParameters;
for (;;)
{
if (!single_trigger)
{
while (updating_screen)
{
for (;;) {
if (!single_trigger) {
while (updating_screen) {
vTaskDelay(pdMS_TO_TICKS(1));
}
if (!stop)
{
if (stop_change)
{
if (!stop) {
if (stop_change) {
i2s_adc_enable(I2S_NUM_0);
stop_change = false;
}
ADC_Sampling(i2s_buff);
new_data = true;
}
else
{
if (!stop_change)
{
else {
if (!stop_change) {
i2s_adc_disable(I2S_NUM_0);
i2s_zero_dma_buffer(I2S_NUM_0);
stop_change = true;
}
}
// Serial.println("CORE1");
Serial.println("CORE1");
vTaskDelay(pdMS_TO_TICKS(300));
}
else
{
else {
float old_mean = 0;
while (single_trigger)
{
while (single_trigger) {
stop = true;
ADC_Sampling(i2s_buff);
float mean = 0;
float max_v, min_v;
peak_mean(i2s_buff, BUFF_SIZE, &max_v, &min_v, &mean);
// signal captured (pp > 0.4V || changing mean > 0.2V) -> DATA ANALYSIS
if ((old_mean != 0 && fabs(mean - old_mean) > 0.2) || to_voltage(max_v) - to_voltage(min_v) > 0.05)
{
//signal captured (pp > 0.4V || changing mean > 0.2V) -> DATA ANALYSIS
if ((old_mean != 0 && fabs(mean - old_mean) > 0.2) || to_voltage(max_v) - to_voltage(min_v) > 0.05) {
float freq = 0;
float period = 0;
uint32_t trigger0 = 0;
uint32_t trigger1 = 0;
// if analog mode OR auto mode and wave recognized as analog
//if analog mode OR auto mode and wave recognized as analog
bool digital_data = !false;
if (digital_wave_option == 1)
{
if (digital_wave_option == 1) {
trigger_freq_analog(i2s_buff, RATE, mean, max_v, min_v, &freq, &period, &trigger0, &trigger1);
}
else if (digital_wave_option == 0)
{
else if (digital_wave_option == 0) {
digital_data = digital_analog(i2s_buff, max_v, min_v);
if (!digital_data)
{
if (!digital_data) {
trigger_freq_analog(i2s_buff, RATE, mean, max_v, min_v, &freq, &period, &trigger0, &trigger1);
}
else
{
else {
trigger_freq_digital(i2s_buff, RATE, mean, max_v, min_v, &freq, &period, &trigger0);
}
}
else
{
else {
trigger_freq_digital(i2s_buff, RATE, mean, max_v, min_v, &freq, &period, &trigger0);
}
single_trigger = false;
new_data = true;
Serial.println("Single GOT");
// return to normal execution in stop mode
//return to normal execution in stop mode
}
vTaskDelay(pdMS_TO_TICKS(1)); // time for the other task to start (low priorit)
vTaskDelay(pdMS_TO_TICKS(1)); //time for the other task to start (low priorit)
}
vTaskDelay(pdMS_TO_TICKS(300));
}

View file

@ -1,14 +1,11 @@
void peak_mean(uint16_t *i2s_buffer, uint32_t len, float *max_value, float *min_value, float *pt_mean)
{
void peak_mean(uint16_t *i2s_buffer, uint32_t len, float * max_value, float * min_value, float *pt_mean) {
max_value[0] = i2s_buffer[0];
min_value[0] = i2s_buffer[0];
mean_filter filter(5);
filter.init(i2s_buffer[0]);
float mean = 0;
for (uint32_t i = 1; i < len; i++)
{
for (uint32_t i = 1; i < len; i++) {
float value = filter.filter((float)i2s_buffer[i]);
if (value > max_value[0])
@ -23,36 +20,31 @@ void peak_mean(uint16_t *i2s_buffer, uint32_t len, float *max_value, float *min_
pt_mean[0] = mean;
}
// true if digital/ false if analog
bool digital_analog(uint16_t *i2s_buffer, uint32_t max_v, uint32_t min_v)
{
//true if digital/ false if analog
bool digital_analog(uint16_t *i2s_buffer, uint32_t max_v, uint32_t min_v) {
uint32_t upper_threshold = max_v - 0.05 * (max_v - min_v);
uint32_t lower_threshold = min_v + 0.05 * (max_v - min_v);
uint32_t digital_data = 0;
uint32_t analog_data = 0;
for (uint32_t i = 0; i < BUFF_SIZE; i++)
{
if (i2s_buffer[i] > lower_threshold)
{
if (i2s_buffer[i] > upper_threshold)
{
// HIGH DIGITAL
for (uint32_t i = 0; i < BUFF_SIZE; i++) {
if (i2s_buffer[i] > lower_threshold) {
if (i2s_buffer[i] > upper_threshold) {
//HIGH DIGITAL
digital_data++;
}
else
{
// ANALOG/TRANSITION
else {
//ANALOG/TRANSITION
analog_data++;
}
}
else
{
// LOW DIGITAL
else {
//LOW DIGITAL
digital_data++;
}
}
// more than 50% of data is analog
//more than 50% of data is analog
if (analog_data < digital_data)
return true;
@ -67,8 +59,7 @@ void trigger_freq_analog(uint16_t *i2s_buffer,
float *pt_freq,
float *pt_period,
uint32_t *pt_trigger0,
uint32_t *pt_trigger1)
{
uint32_t *pt_trigger1) {
float freq = 0;
float period = 0;
bool signal_side = false;
@ -77,25 +68,21 @@ void trigger_freq_analog(uint16_t *i2s_buffer,
uint32_t trigger_temp[trigger_num] = {0};
uint32_t trigger_index = 0;
// get initial signal relative to the mean
if (to_voltage(i2s_buffer[0]) > mean)
{
//get initial signal relative to the mean
if (to_voltage(i2s_buffer[0]) > mean) {
signal_side = true;
}
// waveform repetitions calculation + get triggers time
//waveform repetitions calculation + get triggers time
uint32_t wave_center = (max_v + min_v) / 2;
for (uint32_t i = 1; i < BUFF_SIZE; i++)
{
if (signal_side && i2s_buffer[i] < wave_center - (wave_center - min_v) * 0.2)
{
for (uint32_t i = 1 ; i < BUFF_SIZE; i++) {
if (signal_side && i2s_buffer[i] < wave_center - (wave_center - min_v) * 0.2) {
signal_side = false;
}
else if (!signal_side && i2s_buffer[i] > wave_center + (max_v - wave_center) * 0.2)
{
else if (!signal_side && i2s_buffer[i] > wave_center + (max_v - wave_center) * 0.2) {
freq++;
if (trigger_count < trigger_num)
{
if (trigger_count < trigger_num) {
trigger_temp[trigger_count] = i;
trigger_count++;
}
@ -103,66 +90,62 @@ void trigger_freq_analog(uint16_t *i2s_buffer,
}
}
// frequency calculation
if (trigger_count < 2)
{
//frequency calculation
if (trigger_count < 2) {
trigger_temp[0] = 0;
trigger_index = 0;
freq = 0;
period = 0;
}
else
{
else {
// simple frequency calculation fair enough for frequencies over 2khz (20hz resolution)
//simple frequency calculation fair enough for frequencies over 2khz (20hz resolution)
freq = freq * 1000 / 50;
period = (float)(sample_rate * 1000.0) / freq; // us
period = (float)(sample_rate * 1000.0) / freq; //us
// from 2000 to 80 hz -> uses mean of the periods for precision
if (freq < 2000 && freq > 80)
{
//from 2000 to 80 hz -> uses mean of the periods for precision
if (freq < 2000 && freq > 80) {
period = 0;
for (uint32_t i = 1; i < trigger_count; i++)
{
for (uint32_t i = 1; i < trigger_count; i++) {
period += trigger_temp[i] - trigger_temp[i - 1];
}
period /= (trigger_count - 1);
freq = sample_rate * 1000 / period;
}
// under 80hz, single period for frequency calculation
else if (trigger_count > 1 && freq <= 80)
{
//under 80hz, single period for frequency calculation
else if (trigger_count > 1 && freq <= 80) {
period = trigger_temp[1] - trigger_temp[0];
freq = sample_rate * 1000 / period;
}
}
// setting triggers offset and getting second trigger for debug cursor on drawn_channel1
//setting triggers offset and getting second trigger for debug cursor on drawn_channel1
/*
The trigger function uses a rise porcentage (5%) obove the mean, thus,
the real waveform starting point is some datapoints back.
The resulting trigger gets a negative offset of 5% of the calculated period
*/
uint32_t trigger2 = 0;
if (trigger_temp[0] - period * 0.05 > 0 && trigger_count > 1)
{
if (trigger_temp[0] - period * 0.05 > 0 && trigger_count > 1) {
trigger_index = trigger_temp[0] - period * 0.05;
trigger2 = trigger_temp[1] - period * 0.05;
}
else if (trigger_count > 2)
{
else if (trigger_count > 2) {
trigger_index = trigger_temp[1] - period * 0.05;
if (trigger_count > 2)
trigger2 = trigger_temp[2] - period * 0.05;
}
pt_trigger0[0] = trigger_index;
pt_trigger1[0] = trigger2;
pt_freq[0] = freq;
pt_period[0] = period;
}
void trigger_freq_digital(uint16_t *i2s_buffer,
float sample_rate,
float mean,
@ -170,8 +153,7 @@ void trigger_freq_digital(uint16_t *i2s_buffer,
uint32_t min_v,
float *pt_freq,
float *pt_period,
uint32_t *pt_trigger0)
{
uint32_t *pt_trigger0) {
float freq = 0;
float period = 0;
@ -181,38 +163,32 @@ void trigger_freq_digital(uint16_t *i2s_buffer,
uint32_t trigger_temp[trigger_num] = {0};
uint32_t trigger_index = 0;
// get initial signal relative to the mean
if (to_voltage(i2s_buffer[0]) > mean)
{
//get initial signal relative to the mean
if (to_voltage(i2s_buffer[0]) > mean) {
signal_side = true;
}
// waveform repetitions calculation + get triggers time
//waveform repetitions calculation + get triggers time
uint32_t wave_center = (max_v + min_v) / 2;
bool normal_high = (mean > to_voltage(wave_center)) ? true : false;
if (max_v - min_v > 4095 * (0.4 / 3.3))
{
for (uint32_t i = 1; i < BUFF_SIZE; i++)
{
if (signal_side && i2s_buffer[i] < wave_center - (wave_center - min_v) * 0.2)
{
if (max_v - min_v > 4095 * (0.4 / 3.3)) {
for (uint32_t i = 1 ; i < BUFF_SIZE; i++) {
if (signal_side && i2s_buffer[i] < wave_center - (wave_center - min_v) * 0.2) {
// signal was high, fell -> trigger if normal high
if (trigger_count < trigger_num && normal_high)
{
//signal was high, fell -> trigger if normal high
if (trigger_count < trigger_num && normal_high) {
trigger_temp[trigger_count] = i;
trigger_count++;
}
signal_side = false;
}
else if (!signal_side && i2s_buffer[i] > wave_center + (max_v - wave_center) * 0.2)
{
else if (!signal_side && i2s_buffer[i] > wave_center + (max_v - wave_center) * 0.2) {
freq++;
// signal was low, rose -> trigger if normal low
if (trigger_count < trigger_num && !normal_high)
{
//signal was low, rose -> trigger if normal low
if (trigger_count < trigger_num && !normal_high) {
trigger_temp[trigger_count] = i;
trigger_count++;
}
@ -222,25 +198,21 @@ void trigger_freq_digital(uint16_t *i2s_buffer,
}
freq = freq * 1000 / 50;
period = (float)(sample_rate * 1000.0) / freq; // us
period = (float)(sample_rate * 1000.0) / freq; //us
if (trigger_count > 1)
{
// from 2000 to 80 hz -> uses mean of the periods for precision
if (freq < 2000 && freq > 80)
{
if (trigger_count > 1) {
//from 2000 to 80 hz -> uses mean of the periods for precision
if (freq < 2000 && freq > 80) {
period = 0;
for (uint32_t i = 1; i < trigger_count; i++)
{
for (uint32_t i = 1; i < trigger_count; i++) {
period += trigger_temp[i] - trigger_temp[i - 1];
}
period /= (trigger_count - 1);
freq = sample_rate * 1000 / period;
}
// under 80hz, single period for frequency calculation
else if (trigger_count > 1 && freq <= 80)
{
//under 80hz, single period for frequency calculation
else if (trigger_count > 1 && freq <= 80) {
period = trigger_temp[1] - trigger_temp[0];
freq = sample_rate * 1000 / period;
}
@ -254,7 +226,11 @@ void trigger_freq_digital(uint16_t *i2s_buffer,
trigger_index = 0;
}
pt_trigger0[0] = trigger_index;
pt_freq[0] = freq;
pt_period[0] = period;
}

View file

@ -2,7 +2,7 @@
void debug_buffer() {
ADC_Sampling();
i2s_adc_disable(I2S_NUM_0);
delay(DEBUG_DELAY);
delay(1000);
for (uint32_t i = 0; i < B_MULT * NUM_SAMPLES; i++) {
for (int j = 0; j < 1; j++) {
Serial.println(i2s_buff[i]);

View file

@ -23,20 +23,12 @@ void configure_i2s(int rate) {
i2s_adc_enable(I2S_NUM_0);
}
/*
void ADC_Sampling(uint16_t *i2s_buff){
for (int i = 0; i < B_MULT; i++) {
//TODO i2s_read_bytes is deprecated, replace with new function
i2s_read_bytes(I2S_NUM_0, (char*)&i2s_buff[i * NUM_SAMPLES], NUM_SAMPLES * sizeof(uint16_t), portMAX_DELAY);
}
}
*/
void ADC_Sampling(uint16_t *i2s_buff){
size_t bytes_read; for (int i = 0; i < B_MULT; i++) {
i2s_read(I2S_NUM_0, (void*)&i2s_buff[i * NUM_SAMPLES], NUM_SAMPLES * sizeof(uint16_t), &bytes_read, portMAX_DELAY);
for(size_t ix = 0; ix < bytes_read/2; ix++) i2s_buff[(i * NUM_SAMPLES) + ix] &= 0x0FFF; // 16bit to 12bit conversion 
}
}
void set_sample_rate(uint32_t rate) {
i2s_driver_uninstall(I2S_NUM_0);

View file

@ -12,7 +12,7 @@ int voltage_division[6] = { //screen has 4 divisions, 31 pixels each (125 pixels
thus, the time division is the number
of samples per screen division
*/
float time_division[9] = { //screen has 4 divisions, 60 pixel each (WIDTH pixel of width)
float time_division[9] = { //screen has 4 divisions, 60 pixel each (240 pixel of width)
10,
25,
50,
@ -34,33 +34,26 @@ void menu_handler() {
button();
}
void button()
{
if (btnok == 1 || btnbk == 1 || btnpl == 1 || btnmn == 1)
void button() {
if ( btnok == 1 || btnbk == 1 || btnpl == 1 || btnmn == 1)
{
menu_action = true;
}
if (menu == true)
{
if (set_value)
{
switch (opt)
{
if (set_value) {
switch (opt) {
case Vdiv:
if (btnpl == 1)
{
if (btnpl == 1) {
volts_index++;
if (volts_index >= sizeof(voltage_division) / sizeof(*voltage_division))
{
if (volts_index >= sizeof(voltage_division) / sizeof(*voltage_division)) {
volts_index = 0;
}
btnpl = 0;
}
else if (btnmn == 1)
{
else if (btnmn == 1) {
volts_index--;
if (volts_index < 0)
{
if (volts_index < 0) {
volts_index = sizeof(voltage_division) / sizeof(*voltage_division) - 1;
}
btnmn = 0;
@ -70,20 +63,16 @@ void button()
break;
case Sdiv:
if (btnmn == 1)
{
if (btnmn == 1) {
tscale_index++;
if (tscale_index >= sizeof(time_division) / sizeof(*time_division))
{
if (tscale_index >= sizeof(time_division) / sizeof(*time_division)) {
tscale_index = 0;
}
btnmn = 0;
}
else if (btnpl == 1)
{
else if (btnpl == 1) {
tscale_index--;
if (tscale_index < 0)
{
if (tscale_index < 0) {
tscale_index = sizeof(time_division) / sizeof(*time_division) - 1;
}
btnpl = 0;
@ -93,13 +82,11 @@ void button()
break;
case Offset:
if (btnmn == 1)
{
if (btnmn == 1) {
offset += 0.1 * (v_div * 4) / 3300;
btnmn = 0;
}
else if (btnpl == 1)
{
else if (btnpl == 1) {
offset -= 0.1 * (v_div * 4) / 3300;
btnpl = 0;
}
@ -127,6 +114,7 @@ void button()
default:
break;
}
if (btnbk == 1)
{
@ -163,10 +151,8 @@ void button()
hide_menu();
btnbk = 0;
}
if (btnok == 1)
{
switch (opt)
{
if (btnok == 1) {
switch (opt) {
case Autoscale:
auto_scale = !auto_scale;
break;
@ -185,14 +171,14 @@ void button()
case Stop:
stop = !stop;
Serial.print("Stop : ");
Serial.println(stop);
//Serial.print("Stop : ");
//Serial.println(stop);
set_value = false;
break;
case TOffset:
set_value = true;
// set_value = false;
//set_value = false;
break;
case Single:
@ -225,6 +211,7 @@ void button()
default:
break;
}
btnok = 0;
@ -251,86 +238,71 @@ void button()
}
btnbk = 0;
}
if (btnpl == 1)
{
if (btnpl == 1) {
volts_index++;
if (volts_index >= sizeof(voltage_division) / sizeof(*voltage_division))
{
if (volts_index >= sizeof(voltage_division) / sizeof(*voltage_division)) {
volts_index = 0;
}
btnpl = 0;
v_div = voltage_division[volts_index];
}
if (btnmn == 1)
{
if (btnmn == 1) {
tscale_index++;
if (tscale_index >= sizeof(time_division) / sizeof(*time_division))
{
if (tscale_index >= sizeof(time_division) / sizeof(*time_division)) {
tscale_index = 0;
}
btnmn = 0;
s_div = time_division[tscale_index];
}
}
}
void hide_menu()
{
void hide_menu() {
menu = false;
}
void hide_all()
{
void hide_all() {
menu = false;
info = false;
}
void show_menu()
{
void show_menu() {
menu = true;
}
String strings_vdiv()
{
String strings_vdiv() {
return "";
}
String strings_sdiv()
{
String strings_sdiv() {
return "";
}
String strings_offset()
{
String strings_offset() {
return "";
}
String strings_toffset()
{
String strings_toffset() {
return "";
}
String strings_freq()
{
String strings_freq() {
return "";
}
String strings_peak()
{
String strings_peak() {
return "";
}
String strings_vmax()
{
String strings_vmax() {
return "";
}
String strings_vmin()
{
String strings_vmin() {
return "";
}
String strings_filter()
{
String strings_filter() {
return "";
}

View file

@ -1,22 +1,21 @@
void setup_screen() {
// Initialise the TFT registers
tft.init();
tft.setRotation(3);
tft.setRotation(1);
// Optionally set colour depth to 8 or 16 bits, default is 16 if not spedified
spr.setColorDepth(8);
// Create a sprite of defined size
spr.createSprite(DISPLAY_WIDTH, DISPLAY_HEIGHT);
spr.createSprite(HEIGHT, WIDTH);
// Clear the TFT screen to blue
tft.fillScreen(TFT_BLACK);
}
int data[DISPLAY_WIDTH] = {0};
int data[280] = {0};
/*
float to_scale(float reading) {
float temp = DISPLAY_HEIGHT -
float temp = WIDTH -
(
(
(
@ -27,33 +26,18 @@ float to_scale(float reading) {
(v_div * 6)
)
)
* (DISPLAY_HEIGHT - 1)
* (WIDTH - 1)
- 1;
return temp;
}
*/
float to_scale(float reading) {
float temp = DISPLAY_HEIGHT - (((reading / 4095.0) + (offset / 3.3)) * 3300 / (v_div * 6)) * (DISPLAY_HEIGHT - 1) - 1;
return temp;
}
/*
float to_voltage(float reading) {
return (reading - 20480.0) / 4095.0 * 3.3;
}
*/
float to_voltage(float reading) {
return reading / 4095.0 * 3.3;
}
/*
uint32_t from_voltage(float voltage) {
return uint32_t(voltage / 3.3 * 4095 + 20480.0);
}
*/
uint32_t from_voltage(float voltage) {
return ((uint32_t)(voltage / 3.3 * 4095));
}
void update_screen(uint16_t *i2s_buff, float sample_rate) {
@ -165,11 +149,11 @@ void draw_sprite(float freq,
draw_channel1(trigger, 0, i2s_buff, sample_rate);
}
int shift = DISPLAY_WIDTH - 110;
int shift = 150;
if (menu) {
spr.drawLine( 0, DISPLAY_HEIGHT/2, DISPLAY_WIDTH, DISPLAY_HEIGHT/2, TFT_WHITE); //center line
spr.fillRect(shift, 0, (DISPLAY_HEIGHT/2)-18, (DISPLAY_HEIGHT/2)+15, TFT_BLACK);
spr.drawRect(shift, 0, (DISPLAY_HEIGHT/2)-18, (DISPLAY_HEIGHT/2)+15, TFT_WHITE);
spr.drawLine( 0, 120, 280, 120, TFT_WHITE); //center line
spr.fillRect(shift, 0, 102, 135, TFT_BLACK);
spr.drawRect(shift, 0, 102, 135, TFT_WHITE);
spr.fillRect(shift + 1, 3 + 10 * (opt - 1), 100, 11, TFT_RED);
spr.drawString("AUTOSCALE", shift + 5, 5);
@ -194,34 +178,30 @@ void draw_sprite(float freq,
spr.drawRect(shift, 0, 70, 30, TFT_WHITE);
spr.drawString("P-P: " + String(max_v - min_v) + "V", shift + 5, 5);
spr.drawString(frequency, shift + 5, 15);
//String offset_line = String((2.0 * v_div) / 1000.0 - offset) + "V";
String offset_line = String((3.0 * v_div) / 1000.0 - offset) + "V";
spr.drawString(offset_line, shift + 25, (DISPLAY_HEIGHT/2)-8);
String offset_line = String((2.0 * v_div) / 1000.0 - offset) + "V";
spr.drawString(offset_line, shift + 40, 59);
if (set_value) {
uint16_t t_left = shift+161;
// Plus symbols while setting a value
spr.fillRect(t_left, 0, 11, 11, TFT_BLUE);
spr.drawRect(t_left, 0, 11, 11, TFT_WHITE);
spr.drawLine(t_left+2, 5, t_left+9, 5, TFT_WHITE);
spr.drawLine(t_left+5, 2, t_left+5, 8, TFT_WHITE);
spr.fillRect(229, 0, 11, 11, TFT_BLUE);
spr.drawRect(229, 0, 11, 11, TFT_WHITE);
spr.drawLine(231, 5, 238 , 5, TFT_WHITE);
spr.drawLine(234, 2, 234, 8, TFT_WHITE);
// Minus symbols while setting a value
spr.fillRect(t_left, 124, 11, 11, TFT_BLUE);
spr.drawRect(t_left, 124, 11, 11, TFT_WHITE);
spr.drawLine(t_left+2, 129, t_left+9, 129, TFT_WHITE);
spr.fillRect(229, 124, 11, 11, TFT_BLUE);
spr.drawRect(229, 124, 11, 11, TFT_WHITE);
spr.drawLine(231, 129, 238, 129, TFT_WHITE);
}
}
else if (info) {
spr.drawLine( 0, 120, DISPLAY_WIDTH, 120, TFT_WHITE); //center line
//spr.drawRect(shift + 10, 0, DISPLAY_WIDTH - shift - 20, 30, TFT_WHITE);
spr.drawLine( 0, 120, 280, 120, TFT_WHITE); //center line
//spr.drawRect(shift + 10, 0, 280 - shift - 20, 30, TFT_WHITE);
spr.drawString("P-P: " + String(max_v - min_v) + "V", shift + 15, 5);
spr.drawString(frequency, shift + 15, 15);
spr.drawString(String(int(v_div)) + "mV/div", shift - 100, 5);
spr.drawString(String(int(s_div)) + "uS/div", shift - 100, 15);
//String offset_line = String((2.0 * v_div) / 1000.0 - offset) + "V";
String offset_line = String((3.0 * v_div) / 1000.0 - offset) + "V";
spr.drawString(offset_line, shift + 75, (DISPLAY_HEIGHT/2)-8);
String offset_line = String((2.0 * v_div) / 1000.0 - offset) + "V";
spr.drawString(offset_line, shift + 100, 112);
}
@ -233,15 +213,15 @@ void draw_sprite(float freq,
void draw_grid() {
for (int i = 0; i < (DISPLAY_WIDTH/10); i++) {
for (int i = 0; i < 28; i++) {
spr.drawPixel(i * 10, 40, TFT_WHITE);
spr.drawPixel(i * 10, 80, TFT_WHITE);
spr.drawPixel(i * 10, 120, TFT_WHITE);
spr.drawPixel(i * 10, 160, TFT_WHITE);
spr.drawPixel(i * 10, 200, TFT_WHITE);
}
for (int i = 0; i < DISPLAY_HEIGHT; i += 10) {
for (int j = 0; j < DISPLAY_WIDTH; j += 40) {
for (int i = 0; i < 240; i += 10) {
for (int j = 0; j < 280; j += 40) {
spr.drawPixel(j, i, TFT_WHITE);
}
}
@ -263,7 +243,7 @@ void draw_channel1(uint32_t trigger0, uint32_t trigger1, uint16_t *i2s_buff, flo
trigger0 += index_offset;
uint32_t old_index = trigger0;
float n_data = 0, o_data = to_scale(i2s_buff[trigger0]);
for (uint32_t i = 1; i < DISPLAY_WIDTH; i++) {
for (uint32_t i = 1; i < 280; i++) {
uint32_t index = trigger0 + (uint32_t)((i + 1) * data_per_pixel);
if (index < BUFF_SIZE) {
if (full_pix && s_div > 40 && current_filter == 0) {