mirror of https://github.com/arendst/Tasmota.git
Fix wrong CT channel for Module 48
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@ -2030,38 +2030,40 @@ void calcGammaMultiChannels(uint16_t cur_col_10[5]) {
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void calcGammaBulbs(uint16_t cur_col_10[5]) {
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void calcGammaBulbs(uint16_t cur_col_10[5]) {
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// Apply gamma correction for 8 and 10 bits resolutions, if needed
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// Apply gamma correction for 8 and 10 bits resolutions, if needed
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if (Settings.light_correction) {
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// First apply combined correction to the overall white power
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if ((LST_COLDWARM == Light.subtype) || (LST_RGBCW == Light.subtype)) {
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// channels for white are always the last two channels
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uint32_t cw1 = Light.subtype - 1; // address for the ColorTone PWM
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uint32_t cw0 = Light.subtype - 2; // address for the White Brightness PWM
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uint16_t white_bri10 = cur_col_10[cw0] + cur_col_10[cw1]; // cumulated brightness
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uint16_t white_bri10_1023 = (white_bri10 > 1023) ? 1023 : white_bri10; // max 1023
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if (PHILIPS == my_module_type) { // channel 1 is the color tone, mapped to cold channel (0..255)
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// First apply combined correction to the overall white power
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// Xiaomi Philips bulbs follow a different scheme:
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if ((LST_COLDWARM == Light.subtype) || (LST_RGBCW == Light.subtype)) {
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cur_col_10[cw1] = light_state.getCT10bits();
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// channels for white are always the last two channels
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// channel 0=intensity, channel1=temperature
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uint32_t cw1 = Light.subtype - 1; // address for the ColorTone PWM
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if (Settings.light_correction) { // gamma correction
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uint32_t cw0 = Light.subtype - 2; // address for the White Brightness PWM
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cur_col_10[cw0] = ledGamma10_10(white_bri10_1023); // 10 bits gamma correction
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uint16_t white_bri10 = cur_col_10[cw0] + cur_col_10[cw1]; // cumulated brightness
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} else {
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uint16_t white_bri10_1023 = (white_bri10 > 1023) ? 1023 : white_bri10; // max 1023
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cur_col_10[cw0] = white_bri10_1023; // no gamma, extend to 10 bits
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}
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if (PHILIPS == my_module_type) { // channel 1 is the color tone, mapped to cold channel (0..255)
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// Xiaomi Philips bulbs follow a different scheme:
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cur_col_10[cw1] = light_state.getCT10bits();
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// channel 0=intensity, channel1=temperature
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if (Settings.light_correction) { // gamma correction
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cur_col_10[cw0] = ledGamma10_10(white_bri10_1023); // 10 bits gamma correction
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} else {
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} else {
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// if sum of both channels is > 255, then channels are probably uncorrelated
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cur_col_10[cw0] = white_bri10_1023; // no gamma, extend to 10 bits
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if (white_bri10 <= 1031) { // take a margin of 8 above 1023 to account for rounding errors
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}
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// we calculate the gamma corrected sum of CW + WW
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} else if (Settings.light_correction) {
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uint16_t white_bri_gamma10 = ledGamma10_10(white_bri10_1023);
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// if sum of both channels is > 255, then channels are probably uncorrelated
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// then we split the total energy among the cold and warm leds
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if (white_bri10 <= 1031) { // take a margin of 8 above 1023 to account for rounding errors
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cur_col_10[cw0] = changeUIntScale(cur_col_10[cw0], 0, white_bri10_1023, 0, white_bri_gamma10);
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// we calculate the gamma corrected sum of CW + WW
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cur_col_10[cw1] = changeUIntScale(cur_col_10[cw1], 0, white_bri10_1023, 0, white_bri_gamma10);
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uint16_t white_bri_gamma10 = ledGamma10_10(white_bri10_1023);
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} else {
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// then we split the total energy among the cold and warm leds
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cur_col_10[cw0] = ledGamma10_10(cur_col_10[cw0]);
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cur_col_10[cw0] = changeUIntScale(cur_col_10[cw0], 0, white_bri10_1023, 0, white_bri_gamma10);
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cur_col_10[cw1] = ledGamma10_10(cur_col_10[cw1]);
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cur_col_10[cw1] = changeUIntScale(cur_col_10[cw1], 0, white_bri10_1023, 0, white_bri_gamma10);
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}
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} else {
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cur_col_10[cw0] = ledGamma10_10(cur_col_10[cw0]);
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cur_col_10[cw1] = ledGamma10_10(cur_col_10[cw1]);
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}
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}
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}
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}
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}
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if (Settings.light_correction) {
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// then apply gamma correction to RGB channels
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// then apply gamma correction to RGB channels
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if (LST_RGB <= Light.subtype) {
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if (LST_RGB <= Light.subtype) {
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for (uint32_t i = 0; i < 3; i++) {
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for (uint32_t i = 0; i < 3; i++) {
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@ -2069,8 +2071,8 @@ void calcGammaBulbs(uint16_t cur_col_10[5]) {
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}
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}
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}
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}
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// If RGBW or Single channel, also adjust White channel
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// If RGBW or Single channel, also adjust White channel
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if ((LST_COLDWARM != Light.subtype) && (LST_RGBCW != Light.subtype)) {
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if ((LST_SINGLE == Light.subtype) || (LST_RGBW == Light.subtype)) {
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cur_col_10[3] = ledGamma10_10(cur_col_10[3]);
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cur_col_10[Light.subtype - 1] = ledGamma10_10(cur_col_10[Light.subtype - 1]);
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}
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}
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}
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}
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}
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}
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