DART-SD410 Android Examples: Difference between revisions
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{{PageHeader|DART-SD410 - Using Peripherals}} __toc__ | {{PageHeader|DART-SD410 - Using Peripherals}} __toc__ | ||
This WIKI describes how to use some simple peripheral devices available on VAR- | This WIKI describes how to use some simple peripheral devices available on VAR-SD410CustomBoard. | ||
=Using User LED= | =Using User LED= | ||
User LED1 (D6) connected to GPIO21 of the CPU. | User LED1 (D6) connected to GPIO21 of the CPU. | ||
The LED1 is defined in the apq8016-var- | The LED1 is defined in the apq8016-var-sd410.dtsi file under gpio-leds section. | ||
<pre> | <pre> | ||
general1 { | general1 { | ||
Line 39: | Line 39: | ||
= Using GPIO = | = Using GPIO = | ||
User LED2 (D9) connected to GPIO120 of the CPU. The LED1 is not defined in the apq8016-var- | User LED2 (D9) connected to GPIO120 of the CPU. The LED1 is not defined in the apq8016-var-sd410.dtsi file under gpio-leds section.</br> | ||
This allow user acces to this LED as GPIO device. | This allow user acces to this LED as GPIO device. | ||
To change the state of the LED via serial console type: | To change the state of the LED via serial console type: | ||
Line 117: | Line 117: | ||
= Using RTC = | = Using RTC = | ||
There are two RTC devices defined in the system. One is inside DART-SD410 PMIC chip and the second is on VART- | There are two RTC devices defined in the system. One is inside DART-SD410 PMIC chip and the second is on VART-SD410CustomBoard.<br/> | ||
The main RTC device is DS1307 that is assembled on VART- | The main RTC device is DS1307 that is assembled on VART-SD410CustomBoard. | ||
It can be accessed via console in the following manner: | It can be accessed via console in the following manner: | ||
<pre> | <pre> | ||
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Switching screens is done via Fastboot. | Switching screens is done via Fastboot. | ||
To switch follow the scenario: | To switch follow the scenario: | ||
* Connect USB cable between Host PC and VAR- | * Connect USB cable between Host PC and VAR-SD410CustomBoard (J20) | ||
* Press on Back button (SW8) | * Press on Back button (SW8) | ||
* Cycle the power or press Reset button (SW1) | * Cycle the power or press Reset button (SW1) | ||
Line 245: | Line 245: | ||
</pre> | </pre> | ||
= Rotating LVDS screen = | = Rotating LVDS screen = | ||
There is no sensors on the VAR- | There is no sensors on the VAR-SD410CustomBoard so automatic screen rotation is not available.<br> | ||
To rotate LVDS display the property 'persist.panel.orientation' can be changed.<br> | To rotate LVDS display the property 'persist.panel.orientation' can be changed.<br> | ||
<pre> | <pre> |
Revision as of 14:08, 15 February 2016
This WIKI describes how to use some simple peripheral devices available on VAR-SD410CustomBoard.
Using User LED
User LED1 (D6) connected to GPIO21 of the CPU. The LED1 is defined in the apq8016-var-sd410.dtsi file under gpio-leds section.
general1 { gpios = <&msm_gpio 21 0>; label = "led1"; linux,default-trigger = "none"; default-state = "off"; retain-state-suspended; };
You can access the LED device via serial console by:
$ su # cd /sys/class/leds/led1 # echo 1 > brightness Writing any value other then 0 will turn the led on # echo 0 > brightness The led will turn off
You can view available triggers by typing:
# cat trigger The output will be: [none] boot-indication usb-online mmc0 mmc1 battery-charging-or-full battery-charging battery-full battery-charging-blink-full-solid wlan-indication-led
Set the trigger to mmc0 device by typing:
# echo mmc0 > trigger
Test it by reading mmc0 device:
# dd if=/dev/block/mmcblk0 of=/dev/null bs=128 count=1000000
Using GPIO
User LED2 (D9) connected to GPIO120 of the CPU. The LED1 is not defined in the apq8016-var-sd410.dtsi file under gpio-leds section.
This allow user acces to this LED as GPIO device.
To change the state of the LED via serial console type:
$ su # cd /sys/class/gpio # echo 1022 > export This line creates a new directory gpio1022 The number 1022 calculated as 120 + 902. 120 is the GPIO number, 902 is static offset for CPU gpio. So changing any other GPIO will lead to 902 + GPIO number. # cd gpio1022 # echo out > direction # echo 1 > value The led will turn on #echo 0 > value The led will turn off
To read the current state type:
# cat value The output will be 0
You can change active state to active low.
# echo 1 > active_low # echo 0 > value The led is active low, writing 0 will turn on the led. # echo 1 > value The led is active low, writing 1 will turn off the led.
The Boot Select switch (SW3) connected to CPU GPIO81 to read its value use:
# cd /sys/class/gpio # echo 983 > export # cd gpio983 # cat value If the switch is in OFF position the output is 0. If the switch is in ON position the output is 1.
To see all allocated GPIOs in the system type:
# cat /sys/kernel/debug/gpio The output will be: GPIOs 577-608, platform/qcom,smp2pgpio-ssr-smp2p-4-out.19, master-kernel: GPIOs 609-640, platform/qcom,smp2pgpio-ssr-smp2p-4-in.18, slave-kernel: GPIOs 641-672, platform/qcom,smp2pgpio-ssr-smp2p-1-out.13, master-kernel: GPIOs 673-704, platform/qcom,smp2pgpio-ssr-smp2p-1-in.12, slave-kernel: GPIOs 705-736, platform/qcom,smp2pgpio-smp2p-4-out.16, smp2p: GPIOs 737-768, platform/qcom,smp2pgpio-smp2p-4-in.14, smp2p: GPIOs 769-800, platform/qcom,smp2pgpio-smp2p-1-out.10, smp2p: GPIOs 801-832, platform/qcom,smp2pgpio-smp2p-1-in.8, smp2p: GPIOs 833-864, platform/qcom,smp2pgpio-smp2p-7-out.6, smp2p: GPIOs 865-896, platform/qcom,smp2pgpio-smp2p-7-in.4, smp2p: GPIOs 897-900, spmi/qpnp-pin-ffffffc0319b4c00, pm8916-gpio: gpio-899 (qcom,hub-reset-gpio ) out hi gpio-900 (qcom,sw-sel-gpio ) in lo GPIOs 901-901, spmi/qpnp-pin-ffffffc0319b4800, pm8916-mpp: GPIOs 902-1023, platform/1000000.pinctrl, msm_tlmm_gpio: gpio-914 (ft5x06_reset_gpio ) out hi gpio-915 (ft5x06_irq_gpio ) in hi gpio-922 (adv7533_hpd_irq_gpio) in lo gpio-923 (led1 ) out lo gpio-933 (adv7533_irq_gpio ) in hi gpio-934 (disp_rst_n ) in hi gpio-940 (7864900.sdhci cd ) in lo gpio-1009 (volume_up ) in hi gpio-1010 (home ) in hi gpio-1011 (back ) in hi gpio-1022 (sysfs ) out lo gpio-1023 (USB_ID_GPIO ) in hi
From this table you can see that offsets are:
- CPU gpio is 902
- PMIC gpio is 897
- PMIC mpp is 901
Using RTC
There are two RTC devices defined in the system. One is inside DART-SD410 PMIC chip and the second is on VART-SD410CustomBoard.
The main RTC device is DS1307 that is assembled on VART-SD410CustomBoard.
It can be accessed via console in the following manner:
$ su # cd /sys/class/rtc/rtc0 # cat date Output similar to 2000-01-01 # cat time Output similar to 00:00:36
To set the timezone use:
# setprop persist.sys.timezone "America/Chicago"
To set the time and date use:
# date -s 20160119.122100 The format is YYYYMMDD.HHmmss
To read back from the RTC0 device use:
# cat date Output is 2016-01-19 # cat time Output is 18:21:04 Pay attention that RTC stores time without timezone offset
You can use CR1225 lithium cell to run the RTC clock, insert it into battery holder JBT1.
Set the time and remove the power.
Wait for 5 minutes, plug the power in and verify RTC is still running.
Recording and Playing Sound file
To record simple wav file from the headset use the following scenario:
- Plug in standard cellphone headset into Headset Jack (J15) We used Samsung headset.
- use the following commands to test:
$ su Set the mixer parameters to enable headset record # tinymix 'MultiMedia1 Mixer TERT_MI2S_TX' 1 # tinymix 'DEC1 MUX' 'ADC2' # tinymix 'ADC2 MUX' 'INP2' # tinymix 'MultiMedia1 Mixer TERT_MI2S_TX' 1 Record an audio file # tinycap /sdcard/test.wav In the end of recording press ^c The file test.wav will be created in /sdcard folder
To play the recorded file use:
# tinymix 'PRI_MI2S_RX Audio Mixer MultiMedia1' 1 # tinymix 'RX1 MIX1 INP1' 'RX1' # tinymix 'RX2 MIX1 INP1' 'RX2' # tinymix 'RDAC2 MUX' 'RX2' # tinymix 'HPHL' 'Switch' # tinymix 'HPHR' 'Switch' # tinymix 'MI2S_RX Channels' 'Two' # tinyplay /sdcard/test.wav
Capturing Screen snapshot
To save the screen contents to a file use:
$ su # screencap -p /sdcard/screen.png The file screen.png is created in the /sdcard folder
Recording Screen
To record a video file with screen activity use:
$ su # screenrecord /sdcard/screen.avi In the end of record press ^c The file screen.avi is created in the /sdcard folder
Switching Screen
Switching screens is done via Fastboot. To switch follow the scenario:
- Connect USB cable between Host PC and VAR-SD410CustomBoard (J20)
- Press on Back button (SW8)
- Cycle the power or press Reset button (SW1)
- On the host PC use:
To switch to HDMI
$ sudo fastboot oem select-display-panel adv7533_1080p $ sudo fastboot reboot
To switch to LCD
$ sudo fastboot oem select-display-panel $ sudo fastboot reboot
Capturing Camera image
Capture the camera image can be done using GUI or via console.
To capture the Camera image from console use the following:
Start Camera application
$ su # am start -a android.media.action.STILL_IMAGE_CAMERA
Send KEYCODE_CAMERA event (take the picture)
# input keyevent 27
Send KEYCODE_BACK event (exit Camera application)
# input keyevent 4
All this can be done in one line
# am start -a android.media.action.STILL_IMAGE_CAMERA && sleep 1 && input keyevent 27 && input keyevent 4
Testing Internet connection
The wired Ethernet controller connected to DART-SD410 USB port.
To use it the USB Device connector (J20) should not be connected.
For testing use the following scenario:
- Disconnect USB Device connector (J20)
- Connect Ethernet cable into RJ45 Jack (J22)
- On serial console type:
$ su # ping google.com The output will show the ping responces
Rotating LVDS screen
There is no sensors on the VAR-SD410CustomBoard so automatic screen rotation is not available.
To rotate LVDS display the property 'persist.panel.orientation' can be changed.
$ su # setprop persist.panel.orientation 0 This will rotate the screen and put it into landscape mode To return to portrait mode use # setprop persist.panel.orientation 270