# Plasma The Plasma library is intended to drive APA102 / DotStarâ„¢ or WS2812 / NeoPixelâ„¢ LEDs on the Plasma 2040 board, though it can be used with your own custom pins/wiring. - [Notes On PIO Limitations](#notes-on-pio-limitations) - [WS2812](#ws2812) - [Getting Started](#getting-started) - [RGBW and Setting Colour Order](#rgbw-and-setting-colour-order) - [Set An LED](#set-an-led) - [RGB](#rgb) - [HSV](#hsv) - [Set Brightness](#set-brightness) - [APA102](#apa102) - [Getting Started](#getting-started-1) - [Set An LED](#set-an-led-1) - [RGB](#rgb-1) - [HSV](#hsv-1) - [Using the Buttons & RGB LED](#using-the-buttons--rgb-led) - [Buttons](#buttons) - [RGBLED](#rgbled) - [Measuring LED Strip Current Draw](#measuring-led-strip-current-draw) - [Analog](#analog) ## Notes On PIO Limitations The WS2812 and APA102 drivers use the PIO hardware on the RP2040. There are only two PIOs with four state machines each, placing a hard limit on how many separate LED strips you can drive. In most cases you'll use `0` for PIO and `0` for PIO state-machine, but you should change these if you plan on running different strand types together, or if you're using something else that uses PIO. ## WS2812 ### Getting Started Construct a new `WS2812` instance, specifying the number of LEDs, PIO, PIO state-machine and GPIO pin. ```python import plasma from plasma import plasma2040 LEDS = 30 FPS = 60 led_strip = plasma.WS2812(LEDS, 0, 0, plasma2040.DAT) ``` Start the LED strip by calling `start`. This sets up a timer which tells the RP2040 to DMA the pixel data into the PIO (a fast, asyncronous memory->peripheral copy) at the specified framerate. ```python led_strip.start(FPS) ``` ### RGBW and Setting Colour Order Some WS2812-style LED strips have varying colour orders and support an additional white element. Two keyword arguments are supplied to configure this: ```python import plasma from plasma import plasma2040 LEDS = 30 FPS = 60 led_strip = plasma.WS2812(LEDS, 0, 0, plasma2040.DAT, rgbw=True, color_order=plasma.COLOR_ORDER_GRB) ``` The available orders are defined as constants in `plasma`: * `COLOR_ORDER_RGB` * `COLOR_ORDER_RBG` * `COLOR_ORDER_GRB` * `COLOR_ORDER_GBR` * `COLOR_ORDER_BRG` * `COLOR_ORDER_BGR` ### Set An LED You can set the colour of an LED in either the RGB colourspace, or HSV (Hue, Saturation, Value). HSV is useful for creating rainbow patterns. #### RGB Set the first LED - `0` - to Purple `255, 0, 255`: ```python led_strip.set_led(0, 255, 0, 255) ``` #### HSV Set the first LED - `0` - to Red `0.0`: ```python led_strip.set_hsv(0, 0.0, 1.0, 1.0) ``` ### Set Brightness APA102 pixels support global brightness, allowing their brightness to be specified independent of their colour. You can set the overall brightness of your strip by calling: ```python led_strip.set_brightness(15) ``` You can set brightness from `0` to `31`. This directly maps to the 5-bit brightness value sent to the APA102 LEDs. ## APA102 ### Getting Started Construct a new `APA102` instance, specifying the number of LEDs, PIO, PIO state-machine and GPIO data/clock pins. ```python import plasma from plasma import plasma2040 LEDS = 30 FPS = 60 led_strip = plasma.APA102(LEDS, 0, 0, plasma2040.DAT, plasma2040.CLK) ``` Start the LED strip by calling `start`. This sets up a timer which tells the RP2040 to DMA the pixel data into the PIO (a fast, asyncronous memory->peripheral copy) at the specified framerate. ```python led_strip.start(FPS) ``` ### Set An LED You can set the colour of an LED in either the RGB colourspace, or HSV (Hue, Saturation, Value). HSV is useful for creating rainbow patterns. #### RGB Set the first LED - `0` - to Purple `255, 0, 255`: ```python led_strip.set_led(0, 255, 0, 255) ``` #### HSV Set the first LED - `0` - to Red `0.0`: ```python led_strip.set_hsv(0, 0.0, 1.0, 1.0) ``` ## Using the Buttons & RGB LED The `pimoroni` module contains `Button` and `RGBLED` classes to simplify button debounce, auto-repeat and PWM'ing an RGB LED. ```python Button(button, invert=True, repeat_time=200, hold_time=1000) ``` ```python RGBLED(r, g, b, invert=True) ``` The `plasma` module contains a `plasma2040` sub module with constants for the LED and button pins: * `plasma2040.LED_R` = 16 * `plasma2040.LED_G` = 17 * `plasma2040.LED_B` = 18 * `plasma2040.BUTTON_A` = 12 * `plasma2040.BUTTON_B` = 13 * `plasma2040.USER_SW` = 23 ### Buttons Import the `Button` class from the `pimoroni` module and the pin constants for the buttons: ```python from pimoroni import Button from plasma import plasma2040 ``` Set up an instance of `Button` for each button: ```python button_a = Button(plasma2040.BUTTON_A) button_b = Button(plasma2040.BUTTON_B) ``` To get the button state, call `.read()`. If the button is held down, then this will return `True` at the interval specified by `repeat_time` until `hold_time` is reached, at which point it will return `True` every `hold_time / 3` milliseconds. This is useful for rapidly increasing/decreasing values such as hue: ```python state = button_a.read() ``` ### RGBLED Import the `RGBLED` class from `pimoroni` and the pin constants for the LED: ```python from pimoroni import RGBLED from plasma import plasma2040 ``` And set up an instance of `RGBLED` for the LED: ```python led = RGBLED(plasma2040.LED_R, plasma2040.LED_G, plasma2040.LED_B) ``` To set the LED colour, call `.set_rgb(r, g, b)`. Each value should be between 0 and 255: ```python led.set_rgb(255, 0, 0) # Full red led.set_rgb(0, 255, 0) # Full green led.set_rgb(0, 0, 255) # Full blue ``` ## Measuring LED Strip Current Draw Plasma 2040 feasures low-side current sensing, letting you measure how much current a strip of LEDs is drawing. This could be used just for monitoring, or as a way to reduce the maximum brightness of a strip to keep its current draw within the range of the USB port or power supply being used. The `pimoroni` module contains an `Analog` class to simplify the reading of this current draw. ```python Analog(pin, amplifier_gain=1, resistor=0) ``` The `plasma` module contains a `plasma2040` sub module with constants for the current sensing: * `plasma2040.CURRENT_SENSE` = 29 * `plasma2040.ADC_GAIN` = 50 * `plasma2040.SHUNT_RESISTOR` = 0.015 ### Analog Import the `Analog` class from `pimoroni` and the pin and gain constants for the current sensing: ```python from pimoroni import Analog from plasma import plasma2040 ``` And set up an instance of `Analog` for the current sensing: ```python sense = Analog(plasma2040.CURRENT_SENSE, plasma2040.ADC_GAIN, plasma2040.SHUNT_RESISTOR) ``` To read the current draw, call `.read_current()`. The returned value will be in amps (A): ```python print("Current =", sense.read_current(), "A") ```