Introduction: WS2812-B LED With ATMEGA328 UNO V3.0 R3 Board

Picture of WS2812-B LED With ATMEGA328 UNO V3.0 R3 Board


This project combines ICStation WS2812-B Programmable Colorful LED Board with ATMEGA328 UNO V3.0 R3 Board Compatible Arduino UNO R3 to create a visual impact. What's more, if you are having a "Disco" theme party, you will like it. Let me show you how to make one of these things.

Step 1: Parts Required:

Picture of Parts Required:

· Arduino UNO (or compatible board)
· 4 x WS2812-B Programmable Colorful LED Board

· 330 ohm resistor

· 4700 uF 16V Electrolytic Capacitor

· Breadboard

· Female to Male Jumper wires

· Breadboard Jumper wires

· 2.1mm DC Socket with Screw Terminals

· 5V 4A Plugpack power supply

Note: powering this project using batteries is possible, but not recommended, and done at your own risk.

You will also need a Disco Ball Cake which you will have to make(or buy).My wife made this one. And as you will see shortly, the cake on the inside was Pink, because it was a strawberry cake.

Arduino Libraries and IDE
You can get the Arduino IDE from here: I used version 1.6.4, which is probably way out of date... but works fine nonetheless.

You can get information about how to use the FastLED library here: And you can download it from here: FastLED Library I used version 3.0.3, which is also probably out of date.



· FastLED Library: You need to make sure that you have downloaded and installed the FastLED library into your Arduino IDE. The library is included in this sketch otherwise the FastLED functions will not work.

· The "NUM_LEDS" variable: tells the Arduino how many LEDS are in use. In this case, we have 4 LED rings, with each LED ring containing 16 LEDs, and therefore a total of 64 LEDs. If you define a lower number, for example 16, then the sketch would only illuminate the LEDs on the first LED ring.

· The "DATA_PIN" variable: tells the Arduino which Digital Pin to use for data transmission to the LED ring. In this case, I am using Digital Pin 9.

· Other variables: I have a couple of other variables which are used for LED randomization and hue control. Hue is the colour of the LED. By incrementing the hue variable, you can get the LEDs to cycle in a rainbow-like pattern. The "hue" variable is a "byte", which means that it will only go up to a maximum value of 255, before it jumps back down to zero.

Initialisation Code: If you have a different LED ring to the one in this tutorial, you may have to modify the initialisation code. This LED ring has a WS2812-B chipset (according to the ICStation website), and so this line:

· FastLED.addLeds(leds, NUM_LEDS); Will tell the FastLED library which chipset is being used (NEOPIXEL), the pin used for data transmission (DATA_PIN), the LED array to be controlled (leds), and the number of LEDs to be controlled (NUM_LEDS).
· In the "loop()": section of the code: the "hue" variable is incremented to create a rainbow effect, and a random LED is selected using the FastLED's random8() function.

· The random8(x) function: will randomly choose a number from 0 to x.

· The randomSeed() function: is there to help "truely randomise" the number. This is helped by reading the randomness of a floating analogPin (A0). It doesn't have to be analogPin 0, it can be any unused analog pin.

· leds[rnd].setHSV(hue,255,255): This line sets the random LED to have a hue equal to the "hue" variable, saturation equal to 255, and brightness equal to 255. Saturation equal to zero will make the LED shine white. Brightness of zero essentially turns the LED OFF.

· No physical changes will be made to the LED ring display until a message is sent from the Arduino to the Digital input pin of the LED ring. This message is transmitted when you call the; function. This tells the LED rings to update their display with the information contained within the led array (leds). So if you set all LEDs to turn on, the board will not illuminate the LEDs until the; function is called. This is important to know - especially when trying to design your own LED sequences.

· The delay(50) line: will set the amount of time between flashes to 50 milliseconds. You can change the delay to increase or decrease the number of flashes per second.

· The leds[i].fadeToBlackBy( 180 ) function: essentially fades the LEDS by 180 units. You can increase or decrease this number to achieve the desired fade speed. Be warned however, that if you forget to call this function or if you fail to fade the LEDs sufficiently, then you may end up with ALL LEDs turning on, which could potentially destroy your Arduino board - i.e. depending on the number of LED rings you have, and how you have chosen to power them.

Step 4: The Cake

Picture of The Cake

· Slide 1 - Base Plate: It is important to create the base
plate with all of the electronics fitted and in working order BEFORE you put the Cake onto it. Trying to fit wires/cables LEDs and circuits under the base plate while there is a Cake ontop is a recipe for disaster. So prepare the base plate first, and then move to the cake making part later.

· Slide 2 - Bake Cake: You will need a couple of hemisphere cake pans to make the two sides of the ball. You have to make a relatively dense cake to withstand the overall weight of the cake, icing and fondant, and to maintain it's shape. Once cooled and chilled, you can place them ontop of each other to form a sphere. They are held together by a layer of icing between them.

· Slide 3 - Fondant Icing: The fondant icing has to be rolled out on a special non-stick mat. We found that adding a bit of flour helped to reduce the stickiness. There are special rollers which ensure that the thickness of the fondant is consistent throughout. You then have to cut them into square pieces (about 1 cm squares worked well for us). The squares are then painted Silver with a special/edible silver fondant glaze. You may need to use a few coats, and allowing it to dry between coats.

· Slide 4 - Iced Cake on Base: The cake can either be iced on or off the base plate... probably better to do it off the base plate. But if you decide to do it on the base plate, you will need to protect the LEDs from stray icing that may fall from the cake (in the process). Once the cake has been fully iced (with icing/frosting), you will need to place the cake into the central position on the board. There may be a chance that the cake may slide from the base... so do what you need to do to make it stay put.

· Slides 5-7 - Place Fondant Squares: While the icing is still soft, you will then need to quickly, methodically and tirelessly place the fondant squares in a horizontal linear pattern around the cake. Work your way towards the north and south poles of the cake doing one row at a time. You can cut a fondant circle for the north pole of the cake. In slide 7, you will see a hole at the top of the cake. This was made to cold a plastic canister inside, which would be used later the hold the decorations in place at the top of the cake. Do this before placing the fondant circle at the top of the cake.

· Slide 8 - Add Glitter: After placing all of the fondant squares onto the cake, it is very possible that some of the Silver glaze may have been wiped off some of the squares. This is where you go over it again with a few more coats of silver glaze, and on the last coat, before it dries, you can sprinkle some edible glitter all around the cake to give it that extra shine.

· Slide 9 - The end product: The final step is to add some wire sparklers and some other decorations to the top of the cake. Push the wires through the fondant cap at the north pole into the canister within. This will hold the wires in place without ruining all of your hard work.

· WS2812-B chipset: This LED ring uses the WS2812-B chipset, and has 4 break-out pins(GND, 5V, Din, Dout)

· Power: To power this module, you need to provide 5V and up to 1A of current

· Signals: To control the LED ring, you need to send signals to it via the Digital Input pin (Din).

You can connect another LED ring to this one by utilising the Digital Output pin (Dout)

Step 5: Power Usage Guide

Picture of Power Usage Guide

· General Rule: Each individual LED on the ring can transmit Red, Green and Blue light.The combinations of these colours can make up any other colour. White light is made up of all three of these colours at the same time. Each individual colour will draw approximately 20mA of current when showing that colour at maximum brightness. When shining white at maximum brightness, the single LED will draw approximately 60mA.

· Power multiplier: If each LED can draw up to 60mA and there are 16 LEDs on a single LED ring, then 16x60mA = 960mA per LED ring. To be safe, and to make the maths easier, you need to make sure that you provide enough current to accommodate 1A per LED ring. So 4 LED rings will need a 5V 4A power supply if you want to get full functionality out of the modules.

Step 6: Fritzing Diagram

Picture of Fritzing Diagram

Connecting ONE LED Ring to the Arduino

· 3 wires: You only need 3 wires to connect to the LED ring. If you only plan to light up a couple of LEDs at any one time this should be ok.
· The SAFE WAY: A safer way to do this is to use an external power supply to power both the Arduino and the LED ring.

· Electrolytic capacitor: By connecting a large 4700 uF 16V Electrolytic capacitor between the positive and negative terminals of power supply leads, with the negative leg of the capacitor attached to the negative terminal of the power supply, you will protect your LED rings from any initial onrush of current.

Protecting Resistor: It is also advisable to place a 300-400 ohm resistor between the Arduino's Digital Pin 9 (D9) and the LED Ring's Digital Input pin (Din). This protects the first LED from potential voltage spikes

Suitable wires: If you plan to chain a few of these LED rings together (see below), then you will probably want to keep the wires as short as possible and use a decent guage wire that can handle the current being drawn through them.

Step 7: Connecting TWO LED Rings to the Arduino

Picture of Connecting TWO LED Rings to the Arduino

Three extra wires:You only need 3 extra wires to connect an additional LED ring. A wire needs to connect the Digital output (Dout) of the first LED ring to the Digital Input (Din) of the 2nd LED ring.

Stay safe: Once again, a safer way to do this is to use an external power supply, a large electrolytic capacitor at the terminals, and a 300-400 ohm resistor between the Arduino and the first LED ring's digital input pin.

Step 8: Connecting FOUR LED Ring to the Arduino

Picture of Connecting FOUR LED Ring to the Arduino

Sixty Four LEDs:You need 3 extra wires for each additional LED ring. 4 LED rings provides a total of 64 LEDs.

Watch the AMPS:At full brightness, this setup could potentially draw up to 4amps (or roughly 1 amp per LED ring)

External Supply essential: It is essential to use an external power supply to power these LEDs when there are so many of them. If you don't use an external power supply and you accidentally illuminate ALL of the LEDs, then you are likely to damage the microcontroller from excessive current draw.

Step 9: Connection Tables

Picture of Connection Tables

How to connect ONE LED Ring to the Arduino

Step 10: How to Connect TWO LED Rings to the Arduino

Picture of How to Connect TWO LED Rings to the Arduino

Step 11: Conclusion

Picture of Conclusion

In this tutorial we showed you how to go about decorating a Disco Ball cake and also how to use the RGB LED rings from ICStation.

The four products' link in ICStation:

Thanks for our friends Scott and his family having made such awesome presentation about Led.

The original source of the content came from our friend Scott:

If you like this passage, please share with your fiends.

If you think you can make a better review,please comment.

If you have more ideas about IC products, please contact us mail


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