Difference between revisions of "Wiring a Pixel to an external SSR"

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(Created page with "It's possible to rewire a pixel to drive 3 channels of a DC SSR instead of the RGB LED. By so doing, you can gain control to other devices by using your normal pixel control d...")
 
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It's possible to rewire a pixel to drive 3 channels of a DC SSR instead of the RGB LED. By so doing, you can gain control to other devices by using your normal pixel control data stream. A caveat is that in your sequencing, you need to remember which channels these devices are so you don't get confused. This example uses the Bullet or Square pixel using the WS2811 chip as the example and 5vdc power. Pixels that are powered via 12vdc may not work with this method unless the measured output voltage from the WS2811 chip doesn't exceed what the DC SSR can use as its control signal, which is usually 5vdc.
 
It's possible to rewire a pixel to drive 3 channels of a DC SSR instead of the RGB LED. By so doing, you can gain control to other devices by using your normal pixel control data stream. A caveat is that in your sequencing, you need to remember which channels these devices are so you don't get confused. This example uses the Bullet or Square pixel using the WS2811 chip as the example and 5vdc power. Pixels that are powered via 12vdc may not work with this method unless the measured output voltage from the WS2811 chip doesn't exceed what the DC SSR can use as its control signal, which is usually 5vdc.
  
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== How a WS2811 Chip Works ==
 
First, let's understand how a WS2811 chip works by looking at the PCB for a typical square pixel.
 
First, let's understand how a WS2811 chip works by looking at the PCB for a typical square pixel.
  
 
[[File:Guts-4.png|200px|center]]
 
[[File:Guts-4.png|200px|center]]
Notice there are TWO ground pads, TWO 5v pads, a DI (data in) and a DO (data out) pad, and arrows that indicate the direction of the data flow. Also notice the four holes intended for a common anode RGB led (R, +, G, B). Data, power and ground comes into the chip, the chip lights the appropriate color of the LED, and extra data, power and ground goes back out to the next pixel in line. A round bullet pixel has the same connection pads and the only difference is that they're on either side of the PCB instead of all on the bottom side.
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::Notice there are TWO ground pads, TWO 5v pads, a DI (data in) and a DO (data out) pad, and arrows that indicate the direction of the data flow. Also notice the four holes intended for a common anode RGB led (R, +, G, B). Data, power and ground comes into the chip, the chip lights the appropriate color of the LED, and extra data, power and ground goes back out to the next pixel in line.  
  
How this works is that since a pixel requires three channels to light the LED, connecting the LED outputs to a CAT5 cable instead of to an LED and plugging that cable into a DC SSR gives you 3 channels of complete control, including dimming capability. Slick! Does this also work with AC SSRs? Yes and no. Yes you will have simple on/off control with an AC SSR, but you won't have dimming ability.
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[[File:Bullet_pixel.png|200px|center]]
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::A round bullet pixel has the same connection pads and the only difference is that they're on either side of the PCB instead of all on the bottom side.
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== Wiring Connections ==
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::How this works is that since a pixel requires three channels to light the LED, connecting the LED outputs to a CAT5 cable instead of to an LED and plugging that cable into a DC SSR gives you 3 channels of complete control, including dimming capability. Slick! Does this also work with AC SSRs? Yes and no. Yes you will have simple on/off control with an AC SSR, but you won't have dimming ability.

Revision as of 08:41, 20 May 2017

It's possible to rewire a pixel to drive 3 channels of a DC SSR instead of the RGB LED. By so doing, you can gain control to other devices by using your normal pixel control data stream. A caveat is that in your sequencing, you need to remember which channels these devices are so you don't get confused. This example uses the Bullet or Square pixel using the WS2811 chip as the example and 5vdc power. Pixels that are powered via 12vdc may not work with this method unless the measured output voltage from the WS2811 chip doesn't exceed what the DC SSR can use as its control signal, which is usually 5vdc.

How a WS2811 Chip Works

First, let's understand how a WS2811 chip works by looking at the PCB for a typical square pixel.

Guts-4.png
Notice there are TWO ground pads, TWO 5v pads, a DI (data in) and a DO (data out) pad, and arrows that indicate the direction of the data flow. Also notice the four holes intended for a common anode RGB led (R, +, G, B). Data, power and ground comes into the chip, the chip lights the appropriate color of the LED, and extra data, power and ground goes back out to the next pixel in line.
Bullet pixel.png
A round bullet pixel has the same connection pads and the only difference is that they're on either side of the PCB instead of all on the bottom side.

Wiring Connections

How this works is that since a pixel requires three channels to light the LED, connecting the LED outputs to a CAT5 cable instead of to an LED and plugging that cable into a DC SSR gives you 3 channels of complete control, including dimming capability. Slick! Does this also work with AC SSRs? Yes and no. Yes you will have simple on/off control with an AC SSR, but you won't have dimming ability.