Difference between revisions of "PineTime"
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== Component Datasheets == | == Component Datasheets == | ||
PMU (Power Management Unit) information: | |||
* [https://files.pine64.org/doc/datasheet/pinetime/SGM40561.pdf SGMicro SGM40561 Single Cell Charger Datasheet] | |||
* [https://files.pine64.org/doc/datasheet/pinetime/SGMICRO-SGM2036.pdf SGMicro SGM2036 3.3V Low Power Low Dropout RF Linear Regulator Datasheet] | |||
SPI Flash information: | SPI Flash information: |
Revision as of 17:49, 13 February 2023
The PineTime is a free and open source smartwatch capable of running custom-built open operating systems. Some of the notable features include a heart rate monitor, a week-long battery, and a capacitive touch IPS display that is legible in direct sunlight. It is a fully community driven side-project which anyone can contribute to, allowing you to keep control of your device.
Frequently asked questions / Getting started
Read these first!
- Upgrading your new PineTime to InfiniTime 1.0.0
- Frequently Asked Questions about the PineTime
- PineTime Devkit Wiring
- Reprogramming the PineTime (development kit)
- Switching your PineTime between InfiniTime and Wasp-os
Default OS
The current default operating system on the PineTime is called InfiniTime, you can find more information about the firmware on its GitHub page. First devkits shipped with a proprietary custom firmware.
You can find a list of available firmware and other software here: PineTime Development
Companion Apps
PineTime/InfiniTime needs a companion app to e.g. upload a firmware, get notifications from a phone, or just get the date/time. Here are some companion apps:
- Gadgetbridge (Android >= 4.4) - Companion mobile app, supports updating firmware/bootloader, send notifications, etc.
- Amazfish (SailfishOS and Linux) - Companion mobile and desktop app, supports updating firmware/bootloader, send notifications, etc.
- Siglo (Linux) - Companion desktop app.
- PinetimeFlasher (Windows) - Companion desktop app, only supports flashing firmware.
- nRFConnect (iOS) - Only supports flashing firmware. The app is closed source and versions after 4.24.3 don't work for the PineTime anymore
- InfiniLink (iOS) - Companion mobile app in development. Supports updating firmware/bootloader, setting date and time, Apple Music controls, and battery and heart rate data.
- itd (Linux)
Short overview / Specifications
Dimensions: 37.5 x 40 x 11mm
Weight: 38 grams
IP Rating: IP67 (waterproof to 1 meter (sealed edition!))
Display:
- Size: 1.3 inches (33mm) diagonal
- Type: IPS capacitive touchscreen, RGB 65K colors
- Display Controller: ST7789
- Resolution: 240x240 pixels
System on Chip: Nordic Semiconductor nRF52832
Flash: 512KB with additional 4MB SPI NOR
RAM: 64KB
Bluetooth: 5.0 (including Bluetooth Low Energy)
Sensors: Accelerometer, Heart rate sensor
Feedback: Vibration motor
Battery: 170-180mAh 3.8V LiPo
Community
Forum
Chat
- Matrix Channel (No login required to read)
- IRC Server: irc.pine64.org Channel: PineTime
- Telegram group
- Discord server invite link
Developers and coding
- Matrix Channel (No login required to read)
- Telegram group
- Discord server invite link
Development efforts
To read more about development on the PineTime, the projects available and more technical details, check out PineTime Development
Useful articles and blog posts
If you want to dive in to the ecosystem, here's a short list of various articles and blog posts that can help you set up your soft- or hardware development environment.
- Using the PineTime in production (January 2021)
- Sneak Peek of PineTime Smart Watch… And why it’s perfect for teaching IoT
- Building a Rust Driver for PineTime’s Touch Controller
- Porting (druid) Rust Widgets to PineTime Smart Watch
- Optimising PineTime’s Display Driver with Rust and Mynewt
- Getting Started with Zephyr RTOS on Nordic nRF52832 hackaBLE
- Removing the lock and installing another firmware on the nRF52832 using CMSIS-DAP dongle on Linux
- Build, program and debug NRF52 project with JLink, CMake and CLion
- Using CLion for Nordic nRF52 projects
- Flashing your PineTime using an ST-Link and OpenOCD
- Zephyrlabs: just a bunch of watchfaces made for the pinetime
- Creating a stopwatch in Pinetime (with Infinitime)
Hardware
Display
Note: The factory-default software on the PineTime does not auto-detect the display being disconnected when it has already booted. That can cause garbled output, to fix it just restart the PineTime.
The display is driven using the ST7789 display controller. Use the following pins to drive the screen:
PineTime pin | ST7789 pin |
---|---|
LCD_SCK (P0.02) | SPI clock |
LCD_SDI (P0.03) | SPI MOSI |
LCD_RS (P0.18) | Command/Data pin (CD) |
LCD_CS (P0.25) | Chip select |
LCD_RESET (P0.26) | Display reset |
LCD_BACKLIGHT_{LOW,MID,HIGH} | Backlight (active low) |
Notes:
- Chip select must be held low while driving the display. It must be high when using other SPI devices on the same bus (such as external flash storage) so that the display controller won't respond to the wrong commands.
- SPI must be used in mode 3. Mode 0 (the default) won't work.
- LCD_BACKLIGHT_* is used to enable the backlight. Set at least one to low to see anything on the screen.
- Use SPI at 8MHz (the fastest clock available on the nRF52832) because otherwise refreshing will be super slow.
References:
Battery measurement
Reading whether the PineTime has power attached is easy: simply read the charge indication pin (P0.12). When it is high it is running on battery, when it is low it is charging.
Reading the battery voltage is a bit harder. For that you can use the battery voltage pin on P0.31 (AIN7). The returned value is 12 bits, which means it is 0..4095. You can get the measured voltage with the following formula, assuming a reference voltage of 3.3V (this is configurable in the ADC):
adcVoltage = adcValue / (4095 / 3.3)
The measured voltage is actually half of the actual battery voltage, because the ADC is connected between a voltage divider where both resistors are 1MΩ. This can be corrected by multiplying the value:
batteryVoltage = adcValue * 2 / (4095 / 3.3)
It's often better to avoid floating point values on embedded systems and in this case there is no reason to use float at all, we can just represent the value in millivolts. Therefore the formula can be simplified to:
batteryVoltage = adcValue * 2000 / (4095 / 3.3) batteryVoltage = adcValue * 2000 / 1241
Converting this voltage to an estimated capacity in percent requires a more complicated algorithm, because Lithium-ion batteries have a non-linear discharge curve.
Button
The button on the side of the PineTime is disabled by default. To enable it, drive the button out pin (P0.15) high.
While enabled, the button in pin (P0.13) will be high when the button is pressed, and low when it is not pressed.
Touch panel
The touch panel is controlled by a Hynitron CST816S chips. Unfortunately, there is not much information about this chip on the internet apart from the datasheet below and a reference driver. This is enough to implement a basic driver, but crucial information needed to implement advanced functionalities are missing (I²C protocol and registers, timings, power modes,...).
Pins
- P0.10 : Reset
- P0.28 : Interrupt (signal to the CPU when a touch event is detected)
- P0.06 : I²C SDA
- P0.07 : I²C SCL
I²C
- Device address : 0x15
- Frequency : from 10Khz to 400Khz
NOTE: The controller go to sleep when no event is detected. In sleep mode, the controller does not communicate on the I²C bus (it appears disconnected). So, for the communication to work, you need to tap on the screen so that the chip wakes-up.
NOTE: The I²C bus, also known as TWI bus has known issues, make sure to write your TWI driver with timeouts.
Touch events
Touch information is available from the 63 first registers of the controller. Remember: the device is in sleep mode when no touch event is detected. It means that you can read the register only when the touch controller detected an event. You can use the Interrupt pin to detect such event in the software.
These 63 bytes contain up to 10 touch point (X, Y, event type, pressure,...) :
Byte | Bit7 | Bit6 | Bit5 | Bit4 | Bit3 | Bit2 | Bit1 | Bit0 |
---|---|---|---|---|---|---|---|---|
0 | ? | |||||||
1 | GestureID : (Gesture code ,
0x00: no gesture, 0x01: Slide down, 0x02: Slide up, 0x03: Slide left, 0x04: Slide right, 0x05: Single click, 0x0B: Double click, 0x0C: Long press) | |||||||
2 | ? | Number of touch points | ||||||
3 | Event (0 = Down, 1 = Up, 2 = Contact) | ? | X (MSB) coordinate | |||||
4 | X (LSB) coordinate | |||||||
5 | ? | Touch ID | Y (MSB) coordinate | |||||
6 | Y (LSB) coordinate | |||||||
7 | Pressure (?) | |||||||
8 | Miscellaneous (?) |
Bytes 3 to 8 are repeated 10 times (10*6 + 3 = 63 bytes).
NOTES
- The touch controller seems to report only 1 touch point
- Fields X, Y, Number of touch points and touch ID are updated. The others are always 0.
Registers
The reference driver specifies some registers and value, but there is no information about them:
Register | Address | Description |
---|---|---|
HYN_REG_INT_CNT | 0x8F | |
HYN_REG_FLOW_WORK_CNT | 0x91 | |
HYN_REG_WORKMODE | 0x00 | 0 = WORK, 0x40 = FACTORY |
HYN_REG_CHIP_ID | 0xA3 | |
HYN_REG_CHIP_ID2 | 0x9F | |
HYN_REG_POWER_MODE | 0xA5 | 0x03 = SLEEP (reset the touchpanel using the reset pin before using this register : pin_low, delay 5ms, pin_high, delay 50ms then write 3 to register 0xA5) |
HYN_REG_FW_VER | 0xA6 | |
HYN_REG_VENDOR_ID | 0xA8 | |
HYN_REG_LCD_BUSY_NUM | 0xAB | |
HYN_REG_FACE_DEC_MODE_EN | 0xB0 | |
HYN_REG_GLOVE_MODE_EN | 0xC0 | |
HYN_REG_COVER_MODE_EN | 0xC1 | |
HYN_REG_CHARGER_MODE_EN | 0x8B | |
HYN_REG_GESTURE_EN | 0xD0 | |
HYN_REG_GESTURE_OUTPUT_ADDRESS | 0xD3 | |
HYN_REG_ESD_SATURATE 0xED | 0xED |
WARNING : Writing the SLEEP command (write 0x05 in HYN_REG_POWER_MODE) seems to freeze the controller (it returns only static values) until the battery is totally drained and the whole system reset. Analysis and debugging is more than welcome!
Accelerometer
The on board accelerometer in devices shipped before July 2021 is a Bosch BMA421, connected to the I2C bus. Devices shipped after July 2021 use a Bosch BMA425 accelerometer.
Pins
- P0.06 : I²C SDA
- P0.07 : I²C SCL
- P0.08 : Interrupt
I2C Device address : 0x18
Accessory
Watch band
The PineTime uses a standard 20mm watch band / strap. There is a thread in the forum discussing this.
Cases
There are no cases for PineTime yet, but some cases for Fitbit are suitable for it. Cases for Fitbit have one microphone hole, which is unnecessary for the PineTime, but otherwise they fit perfectly.
The community designed the following cases:
- PineTime Smart Watch case by dara0s at thingiverse
- PineTime dev kit back fix by joaquimorg at thingiverse
- PineTime dev kit charging holder v4 by zevix81 at thingiverse
- PineTime Charger Travel Case by brett at PrusaPrinters
Datasheets, Schematics and Certifications
Schematics
Note: The part number for the SPI FLASH in the schematic diagram is not correct, the PineTime features a larger external FLASH device, see below.
Chip Datasheets
NORDIC nRF52832 information:
ARMv7-M information:
Component Datasheets
PMU (Power Management Unit) information:
- SGMicro SGM40561 Single Cell Charger Datasheet
- SGMicro SGM2036 3.3V Low Power Low Dropout RF Linear Regulator Datasheet
SPI Flash information:
- XTX XT25F32B 32Mb(4MB) SPI NOR Flash (data sheets for this part are hard to find but it acts similar to other QuadSPI SPI NOR Flash such as Macronix 32Mb(4MB) SPI NOR Flash)
- XTX XT25F32B
- IDs for XT25F32B are: manufacturer (0x0b), device (0x15), memory type (0x40), density (0x16)
LCD Panel:
- 1.3" 240x240 IPS LCD Panel Specification for PineTime
- 11.6" Sitronix LCD Driver/Controller Datasheet
Touchpad information:
- Touchpad Specification for PineTimel
- 11.6" Hynitron CST816S Capacitive Touch Controller Datasheet in Chinese
- Touch Controller Datasheet en
Sensor:
- BOSCH BMA425 Triaxial Acceleration Sensor Datasheet on current PineTime device
- BOSCH BMA421 Triaxial Acceleration Sensor Product Brief on early PineTime device
- TianYiHeXin HRS3300 PPG Heart Rate Sensor Data Sheet