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the order of the colors does not significantly affect the functioning of the circuit. However, the visual appearance and the perception of the voltage levels by the viewer may vary based on the arrangement of the LED colors. Here's an example of how you can arrange the LED colors in increasing voltage level order: 1. Red (Lowest voltage level) 2. Yellow (Intermediate voltage level) 3. Green (Intermediate voltage level) 4. Blue (Intermediate voltage level) 5. White (Highest voltage level) So to sum up , yes you can change the order of colors
@@ElectroMin Thanks for your reply, i have one more doubt. i.e. firstly the green led switched on at 3,5 v which is its forward voltage, then red led switched on at 4.2 volt. does it mean that now forward voltage of green and red led has added up because they are connected in series. Does this rule follow yellow, blue and white also. Please also give forward voltages of all color voltages
@@sridharkrishnappanavanerth3388 Yes, in a series circuit, the forward voltages of the LEDs add up. I will describe the process of the circuit Green LED (Forward voltage: 2.0 to 2.4 volts): At 3.5 volts, the green LED starts turning on because the forward voltage is reached. It is the first LED in the series, and the voltage across it is around 3.5 volts. Red LED (Forward voltage: 1.8 to 2.2 volts): At this point, the voltage across the green LED is already around 3.5 volts. To turn on the red LED, you need an additional voltage equal to its forward voltage, which is 1.8 to 2.2 volts. So, the total voltage required for both LEDs to turn on is around 3.5 volts (green) + 1.8 to 2.2 volts (red) = 5.3 to 5.7 volts ( in our experiment red turns on at 4,2 volts ) This rule would be applied for the rest of the leds , for example yellow : 3.5 volts (green) + 1.8 to 2.2 volts (red) + 2.0 to 2.2 yellow forward voltage = 7.3 to 8.9 volts and so on Keep in mind that these are general ranges, and actual forward voltage values might differ slightly based on the specific manufacturer and LED model. In our example red turns on at 4,2v however it has to be around 5,3 ( there is also a bit delay between the breadboard video and power supply video which can also be the reason why these numbers don’t match But to sum up always green led (3,5V) + the forward voltage of the next led in series You can search the forward voltages of the LEDs in internet Please let me know if you have further questions
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Nice video 👍
Thanks 🙏
Cool👌🏼
👍👍
Sir, can we change the order of color Leds? i.e. White, Blue, Yellow, Red then Green. Please explain.
the order of the colors does not significantly affect the functioning of the circuit. However, the visual appearance and the perception of the voltage levels by the viewer may vary based on the arrangement of the LED colors.
Here's an example of how you can arrange the LED colors in increasing voltage level order:
1. Red (Lowest voltage level)
2. Yellow (Intermediate voltage level)
3. Green (Intermediate voltage level)
4. Blue (Intermediate voltage level)
5. White (Highest voltage level)
So to sum up , yes you can change the order of colors
@@ElectroMin Thanks for your reply, i have one more doubt. i.e. firstly the green led switched on at 3,5 v which is its forward voltage, then red led switched on at 4.2 volt. does it mean that now forward voltage of green and red led has added up because they are connected in series. Does this rule follow yellow, blue and white also. Please also give forward voltages of all color voltages
If red has the lowest forward voltage then why didn't red led glow first instead of green led?
@@sridharkrishnappanavanerth3388 Yes, in a series circuit, the forward voltages of the LEDs add up.
I will describe the process of the circuit
Green LED (Forward voltage: 2.0 to 2.4 volts): At 3.5 volts, the green LED starts turning on because the forward voltage is reached. It is the first LED in the series, and the voltage across it is around 3.5 volts.
Red LED (Forward voltage: 1.8 to 2.2 volts): At this point, the voltage across the green LED is already around 3.5 volts. To turn on the red LED, you need an additional voltage equal to its forward voltage, which is 1.8 to 2.2 volts. So, the total voltage required for both LEDs to turn on is around 3.5 volts (green) + 1.8 to 2.2 volts (red) = 5.3 to 5.7 volts ( in our experiment red turns on at 4,2 volts )
This rule would be applied for the rest of the leds , for example yellow : 3.5 volts (green) + 1.8 to 2.2 volts (red) + 2.0 to 2.2 yellow forward voltage = 7.3 to 8.9 volts and so on
Keep in mind that these are general ranges, and actual forward voltage values might differ slightly based on the specific manufacturer and LED model. In our example red turns on at 4,2v however it has to be around 5,3 ( there is also a bit delay between the breadboard video and power supply video which can also be the reason why these numbers don’t match
But to sum up always green led (3,5V) + the forward voltage of the next led in series
You can search the forward voltages of the LEDs in internet
Please let me know if you have further questions
@@sridharkrishnappanavanerth3388because green led is the first led in the series circuit
cool project , circuit Diagramm is available?
You can get the Circuit Diagramm at the end of the video 👍
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nice but battery percentage on the thumbnail is flip, 100% should in other side not near the source as you shown on the video
Puedes regalar el diagrama?
4:53