kobol-wiki/docs/helios64/pwm.md

6.4 KiB
Raw Blame History

PWM Introduction

PWM, or pulse width modulation is a technique which allows us to adjust the average value of the voltage thats going to the electronic device by varying duty cycle of the power at a fast rate.

The term duty cycle describes the proportion of 'on' time to the regular interval or 'period' of time; a low duty cycle corresponds to low power, because the power is off for most of the time. Duty cycle is expressed in percent, 100% being fully on. When a digital signal is on half of the time and off the other half of the time, the digital signal has a duty cycle of 50% and resembles a "square" wave. When a digital signal spends more time in the on state than the off state, it has a duty cycle of >50%. When a digital signal spends more time in the off state than the on state, it has a duty cycle of <50%. Here is a pictorial that illustrates these three scenarios:

PWM duty cycle

PWM Fan Implementation

Type-A

Type A Curve

Type-B

Type B Curve

Type-C

Type C Curve

PWM Fan Schematic

!Fan Control Schematic

Remarks

Description Header P7 Header P6 Remarks
PWM pin PWM0 PWM1 5V tolerant
SENSE pin GPIO4_C5 GPIO4_C7 no kernel module/userspace apps that make use of this pin yet
PWM Frequency 25 kHz 25 kHz defined in device tree

PWM Fan Connector

Fan Connector

Connector Pinout

Pin Function Wire Color
1 GND Black
2 12V Red
3 Sense Yellow
4 Control Blue

Helios64 Temperature Sensors

SoC Temperature Sensor

RK3399 has internal temperature sensor (TS-ADC) for monitoring die temperature. The system has two Temperature Sensors, channel 0 is for CPU, channel 1 is for GPU.

The sensor has -40~125°C temperature range and 5°C temperature resolution.

Board Temp Sensor

Helios64 has a Digital Temperature Sensor with 2wire Interface (NCT75 Datasheet), located on top side of the board near RTC battery. It is used to read ambient temperature.

PWM Fan Control under Linux

Linux use 8-bit integer to represent duty cycle. PWM value 0 represent 0% duty cycle and PWM value 255 represent 100% duty cycle.

Using SYSFS interface

Linux export the fan control mechanism to SYSFS under hwmon class. List of devices can be checked under /sys/class/hwmon

ls -l /sys/class/hwmon/
total 0
lrwxrwxrwx 1 root root 0 Oct 16 08:38 hwmon0 -> ../../devices/virtual/thermal/thermal_zone0/hwmon0
lrwxrwxrwx 1 root root 0 Oct 16 08:38 hwmon1 -> ../../devices/virtual/thermal/thermal_zone1/hwmon1
lrwxrwxrwx 1 root root 0 Oct 16 08:38 hwmon2 -> ../../devices/platform/ff120000.i2c/i2c-2/2-004c/hwmon/hwmon2
lrwxrwxrwx 1 root root 0 Oct 16 09:29 hwmon3 -> ../../devices/platform/gpio-charger/power_supply/gpio-charger/hwmon3
lrwxrwxrwx 1 root root 0 Oct 16 09:29 hwmon4 -> ../../devices/platform/p7-fan/hwmon/hwmon4
lrwxrwxrwx 1 root root 0 Oct 16 09:29 hwmon5 -> ../../devices/platform/p6-fan/hwmon/hwmon5
lrwxrwxrwx 1 root root 0 Oct 16 09:29 hwmon6 -> ../../devices/platform/ff3d0000.i2c/i2c-4/4-0022/power_supply/tcpm-source-psy-4-0022/hwmon6

!!! info The numbering may different from above example output. It depends on whether the driver built as kernel module or built-in, device initialization order. Take this as consideration when using fancontrol

To identify which hwmon belong to fan, look for p6-fan and p7-fan. On above example

hwmon4 -> ../../devices/platform/p7-fan/hwmon/hwmon4
hwmon5 -> ../../devices/platform/p6-fan/hwmon/hwmon5

To read current PWM

cat /sys/class/hwmon4/pwm1
cat /sys/class/hwmon5/pwm1

To set PWM

echo NEW_PWM_VALUE > /sys/class/hwmon4/pwm1
echo NEW_PWM_VALUE > /sys/class/hwmon5/pwm1

Fancontrol - automated software based fan speed control

fancontrol is a shell script for use with lm_sensors. It reads its configuration from a file, then calculates fan speeds from temperatures and sets the corresponding PWM outputs to the computed values.

sudo apt-get install fancontrol

fancontrol includes pwmconfig script to create automatically a configuration file but it can not be used for Helios64.

UDEV rules

Since hwmon order can be changed between kernel version or even between reboot, on Armbian we use udev rules as workaround. The rules can be found from here (mainline) or here (legacy kernel 4.4) and to be copied to /etc/udev/rules.d/

/dev/fan-p6, /dev/fan-p7, /dev/thermal-cpu and /dev/thermal-board are symlinks generated by the udev rules.

Configuration File

fancontrol uses /etc/fancontrol as configuration file. Below is an example configuration to control fan speed on Helios64.

# Helios64 PWM Fan Control Configuration
# Temp source : /dev/thermal-cpu
INTERVAL=10
FCTEMPS=/dev/fan-p6/pwm1=/dev/thermal-cpu/temp1_input /dev/fan-p7/pwm1=/dev/thermal-cpu/temp1_input
MINTEMP=/dev/fan-p6/pwm1=40 /dev/fan-p7/pwm1=40
MAXTEMP=/dev/fan-p6/pwm1=80 /dev/fan-p7/pwm1=80
MINSTART=/dev/fan-p6/pwm1=60 /dev/fan-p7/pwm1=60
MINSTOP=/dev/fan-p6/pwm1=29 /dev/fan-p7/pwm1=29
MINPWM=20

INTERVAL

This variable defines at which interval in seconds the main loop of fancontrol will be executed.

FCTEMPS

Maps PWM outputs to temperature sensors so fancontrol knows which temperature sensors should be used for calculation of new values for the corresponding PWM outputs.

Fans (fan-p6 & fan-p7) are controlled based on CPU thermal sensor (thermal-cpu) reading.


Following settings can be adjusted by user to tweak further.

MINTEMP

The temperature below which the fan gets switched to minimum speed.

Fans (fan-p6 & fan-p7) runs in minimum speed if the CPU temperature below 40 degree C.

MAXTEMP

The temperature over which the fan gets switched to maximum speed.

Fans (fan-p6 & fan-p7) runs in maximum speed if the CPU temperature above 80 degree C.