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==== Smart LED Interface (NEOLED)
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|=======================
| Hardware source file(s): | neorv32_neoled.vhd |
| Software driver file(s): | neorv32_neoled.c |
| | neorv32_neoled.h |
| Top entity port: | `neoled_o` | 1-bit serial data output
| Configuration generics: | _IO_NEOLED_EN_ | implement NEOLED when _true_
| | _IO_NEOLED_TX_FIFO_ | TX FIFO depth (1..32k, has to be a power of two)
| CPU interrupts: | fast IRQ channel 9 | NEOLED interrupt (see <<_processor_interrupts>>)
|=======================
**Theory of Operation**
The NEOLED module provides a dedicated interface for "smart RGB LEDs" like the WS2812 or WS2811.
These LEDs provide a single interface wire that uses an asynchronous serial protocol for transmitting color
data. Basically, data is transferred via LED-internal shift registers, which allows to cascade an unlimited
number of smart LEDs. The protocol provides a RESET command to strobe the transmitted data into the
LED PWM driver registers after data has shifted throughout all LEDs in a chain.
[NOTE]
The NEOLED interface is compatible to the "Adafruit Industries NeoPixel" products, which feature
WS2812 (or older WS2811) smart LEDs (see link:https://learn.adafruit.com/adafruit-neopixel-uberguide).
The interface provides a single 1-bit output `neoled_o` to drive an arbitrary number of cascaded LEDs. Since the
NEOLED module provides 24-bit and 32-bit operating modes, a mixed setup with RGB LEDs (24-bit color)
and RGBW LEDs (32-bit color including a dedicated white LED chip) is possible.
**Theory of Operation – NEOLED Module**
The NEOLED modules provides two accessible interface registers: the control register _NEOLED_CT_ and the
TX data register _NEOLED_DATA_. The NEOLED module is globally enabled via the control register's
_NEOLED_CT_EN_ bit. Clearing this bit will terminate any current operation, clear the TX buffer, reset the module
and set the `neoled_o` output to zero. The precise timing (implementing the **WS2812** protocol) and transmission
mode are fully programmable via the _NEOLED_CT_ register to provide maximum flexibility.
**RGB / RGBW Configuration**
NeoPixel are available in two "color" version: LEDs with three chips providing RGB color and LEDs with
four chips providing RGB color plus a dedicated white LED chip (= RGBW). Since the intensity of every
LED chip is defined via an 8-bit value the RGB LEDs require a frame of 24-bit per module and the RGBW
LEDs require a frame of 32-bit per module.
The data transfer quantity of the NEOLED module can be configured via the _NEOLED_MODE_EN_ control
register bit. If this bit is cleared, the NEOLED interface operates in 24-bit mode and will transmit bits `23:0` of
the data written to _NEOLED_DATA_ to the LEDs. If _NEOLED_MODE_EN_ is set, the NEOLED interface operates in 32-bit
mode and will transmit bits `31:0` of the data written to _NEOLED_DATA_ to the LEDs.
The mode bit can be configured before writing each new data word in order to support
an arbitrary setup of RGB and RGBW LEDs.
**Theory of Operation – Protocol**
The interface of the WS2812 LEDs uses an 800kHz carrier signal. Data is transmitted in a serial manner
starting with LSB-first. The intensity for each R, G & B (& W) LED chip (= color code) is defined via an 8-bit
value. The actual data bits are transferred by modifying the duty cycle of the signal (the timings for the
WS2812 are shown below). A RESET command is "send" by pulling the data line LOW for at least 50μs.
.WS2812 bit-level protocol - taken from the "Adafruit NeoPixel Überguide"
image::neopixel.png[align=center]
.WS2812 interface timing
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|=======================
| T~total~ (T~carrier~) | 1.25μs +/- 300ns | period for a single bit
| T~0H~ | 0.4μs +/- 150ns | high-time for sending a `1`
| T~0L~ | 0.8μs +/- 150ns | low-time for sending a `1`
| T~1H~ | 0.85μs +/- 150ns | high-time for sending a `0`
| T~1L~ | 0.45μs +/- 150 ns | low-time for sending a `0`
| RESET | Above 50μs | low-time for sending a RESET command
|=======================
**Timing Configuration**
The basic carrier frequency (800kHz for the WS2812 LEDs) is configured via a 3-bit main clock prescaler (_NEOLED_CT_PRSCx_, see table below)
that scales the main processor clock f~main~ and a 5-bit cycle multiplier _NEOLED_CT_T_TOT_x_.
.NEOLED prescaler configuration
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|=======================
| **`NEOLED_CT_PRSCx`** | `0b000` | `0b001` | `0b010` | `0b011` | `0b100` | `0b101` | `0b110` | `0b111`
| Resulting `clock_prescaler` | 2 | 4 | 8 | 64 | 128 | 1024 | 2048 | 4096
|=======================
The duty-cycles (or more precisely: the high- and low-times for sending either a '1' bit or a '0' bit) are
defined via the 5-bit _NEOLED_CT_T_ONE_H_x_ and _NEOLED_CT_T_ZERO_H_x_ values, respecively. These programmable
timing constants allow to adapt the interface for a wide variety of smart LED protocol (for example WS2812 vs.
WS2811).
**Timing Configuration – Example (WS2812)**
Generate the base clock f~TX~ for the NEOLED TX engine:
* processor clock f~main~ = 100 MHz
* _NEOLED_CT_PRSCx_ = `0b001` = f~main~ / 4
_**f~TX~**_ = _f~main~[Hz]_ / `clock_prescaler` = 100MHz / 4 = 25MHz
_**T~TX~**_ = 1 / _**f~TX~**_ = 40ns
Generate carrier period (T~carrier~) and *high-times* (duty cycle) for sending `0` (T~0H~) and `1` (T~1H~) bits:
* _NEOLED_CT_T_TOT_ = `0b11110` (= decimal 30)
* _NEOLED_CT_T_ZERO_H_ = `0b01010` (= decimal 10)
* _NEOLED_CT_T_ONE_H_ = `0b10100` (= decimal 20)
_**T~carrier~**_ = _**T~TX~**_ * _NEOLED_CT_T_TOT_ = 40ns * 30 = 1.4µs
_**T~0H~**_ = _**T~TX~**_ * _NEOLED_CT_T_ZERO_H_ = 40ns * 10 = 0.4µs
_**T~1H~**_ = _**T~TX~**_ * _NEOLED_CT_T_ONE_H_ = 40ns * 20 = 0.8µs
[TIP]
The NEOLED SW driver library (`neorv32_neoled.h`) provides a simplified configuration
function that configures all timing parameters for driving WS2812 LEDs based on the processor
clock frequency.
**TX Data FIFO**
The interface features a TX data buffer (a FIFO) to allow more CPU-independent operation. The buffer depth
is configured via the _IO_NEOLED_TX_FIFO_ top generic (default = 1 entry).
The FIFO size configuration can be read via the _NEOLED_CT_BUFS_x_
control register bits, which result log2(_IO_NEOLED_TX_FIFO_).
When writing data to the _NEOLED_DATA_ register the data is automatically written to the TX buffer. Whenever
data is available in the buffer the serial transmission engine will take it and transmit it to the LEDs.
The data transfer size (_NEOLED_MODE_EN_) can be modified at every time since this control register bit is also buffered
in the FIFO. This allows to arbitrarily mixing RGB and RGBW LEDs in the chain.
Software can check the FIFO fill level via the control register's _NEOLED_CT_TX_EMPTY_, _NEOLED_CT_TX_HALF_
and _NEOLED_CT_TX_FULL_ flags. The _NEOLED_CT_TX_BUSY_ flags provides additional information if the the TX unit is
still busy sending data.
[WARNING]
Please note that the timing configurations (_NEOLED_CT_PRSCx_, _NEOLED_CT_T_TOT_x_,
_NEOLED_CT_T_ONE_H_x_ and _NEOLED_CT_T_ZERO_H_x_) are **NOT** stored to the buffer. Changing
these value while the buffer is not empty or the TX engine is still busy will cause data corruption.
** Strobe Command ("RESET") **
According to the WS2812 specs the data written to the LED's shift registers is strobed to the actual PWM driver
registers when the data line is low for 50μs ("RESET" command, see table above). This can be implemented
using busy-wait for at least 50μs. Obviously, this concept wastes a lot of processing power.
To circumvent this, the NEOLED module provides an option to automatically issue an idle time for creating the RESET
command. If the _NEOLED_CT_STROBE_ control register bit is set, _all_ data written to the data FIFO (via _NEOLED_DATA_,
the actually written data is irrelevant) will trigger an idle phase (`neoled_o` = zero) of 127 periods (= _**T~carrier~**_).
This idle time will cause the LEDs to strobe the color data into the PWM driver registers.
Since the _NEOLED_CT_STROBE_ flag is also buffered in the TX buffer, the RESET command is treated as just another
data word being written to the TX buffer making busy wait concepts obsolete and allowing maximum refresh rates.
**Interrupt**
The NEOLED modules features a single interrupt that is triggered whenever the TX FIFO's fill level
falls below _half-full_ level. In this case software can write up to _IO_NEOLED_TX_FIFO_/2 new data
words to _NEOLED_DATA_ without checking the FIFO status flags.
This highly relaxes time constraints for sending a continuous data stream to the LEDs
(as an idle time beyond 50μs will trigger the LED's a RESET command).
<<<
.NEOLED register map
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|=======================
| Address | Name [C] | Bit(s), Name [C] | R/W | Function
.25+<| `0xffffffd8` .25+<| _NEOLED_CT_ <|`0` _NEOLED_CT_EN_ ^| r/w <| NEOLED enable
<|`1` _NEOLED_CT_MODE_ ^| r/w <| data transfer size; `0`=24-bit; `1`=32-bit
<|`2` _NEOLED_CT_STROBE_ ^| r/w <| `0`=send normal color data; `1`=send RESET command on data write access
<|`3` _NEOLED_CT_PRSC0_ ^| r/w <| 3-bit clock prescaler, bit 0
<|`4` _NEOLED_CT_PRSC1_ ^| r/w <| 3-bit clock prescaler, bit 1
<|`5` _NEOLED_CT_PRSC2_ ^| r/w <| 3-bit clock prescaler, bit 2
<|`6` _NEOLED_CT_BUFS0_ ^| r/- .4+<| 4-bit log2(_IO_NEOLED_TX_FIFO_)
<|`7` _NEOLED_CT_BUFS1_ ^| r/-
<|`8` _NEOLED_CT_BUFS2_ ^| r/-
<|`9` _NEOLED_CT_BUFS3_ ^| r/-
<|`10` _NEOLED_CT_T_TOT_0_ ^| r/w .5+<| 5-bit pulse clock ticks per total single-bit period (T~total~)
<|`11` _NEOLED_CT_T_TOT_1_ ^| r/w
<|`12` _NEOLED_CT_T_TOT_2_ ^| r/w
<|`13` _NEOLED_CT_T_TOT_3_ ^| r/w
<|`14` _NEOLED_CT_T_TOT_4_ ^| r/w
<|`20` _NEOLED_CT_ONE_H_0_ ^| r/w .5+<| 5-bit pulse clock ticks per high-time for sending a one-bit (T~H1~)
<|`21` _NEOLED_CT_ONE_H_1_ ^| r/w
<|`22` _NEOLED_CT_ONE_H_2_ ^| r/w
<|`23` _NEOLED_CT_ONE_H_3_ ^| r/w
<|`24` _NEOLED_CT_ONE_H_4_ ^| r/w
<|`30` _NEOLED_CT_TX_STATUS_ ^| r/- <| transmit engine busy when `1`
<|`31` _NEOLED_CT_TX_EMPTY_ ^| r/- <| TX FIFO is empty
<|`31` _NEOLED_CT_TX_HALF_ ^| r/- <| TX FIFO is _at least_ half full
<|`31` _NEOLED_CT_TX_FULL_ ^| r/- <| TX FIFO is full
<|`31` _NEOLED_CT_TX_BUSY_ ^| r/- <| TX serial engine is busy when set
| `0xffffffdc` | _NEOLED_DATA_ <|`31:0` / `23:0` ^| -/w <| TX data (32-/24-bit)
|=======================
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