10.3inch e-Paper HAT (D)
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Introduction
- This product is a flexible e-Paper HAT (D), 10.3 inches, with a resolution of 1872×1404. It equips with IT8951 as the controller, can be controlled by USB/SPI/I80 interface, and supports partial refresh.
- Compared with ordinary e-Paper screens, it is thinner and lighter.
- It has the advantages of low power consumption, wide viewing angle, and clear display after power failure. It is often used in display applications such as e-book readers, ink screen displays, and industrial instruments.
- As the screen of 10.3inch e-Paper is large, the glass panel and FPC are fragile, please be careful when using it for developing. we recommend you reinforce the FPC with scotch tape when developing. Please connect all the cables before powering the device, the device cannot support a hot plug.
- There are two versions: raw panel and HAT. The driver board (IT8951) is required for the raw panel. If you are the first time buying this e-paper, we recommend you choose the HAT version which comes with the driver board.
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Features
- No backlight, keeps displaying last content for a long time even when power down
- Low power consumption, basically power is only required for refreshing
- Based on Raspberry Pi 40PIN GPIO interface design, suitable for Raspberry Pi series motherboards
- USB/SPI/I80/I2C interface, for connecting with host boards like Raspberry Pi/Nucleo, etc.
- Comes with development resources and manual (examples for Raspberry Pi/STM32)
Specifications
- Operating voltage: 5V
- Interface: USB/SPI/I80/I2C
- Outline dimension: 227.7mm × 165.8mm × 0.647mm
- Display size: 209.664mm × 157.248mm
- Dot pitch: 0.112mm × 0.112mm
- Resolution: 1872 × 1404
- Display color: black, white
- Gray scale: 2-16 (1-4 bit)
- Full refresh time: 450ms
- Total refresh power: 1.2W(typ.)
- Total standby power: 0.1W(typ.)
- Viewing angle: >170°
Working principle
This product is an E-paper device adopting the image display technology of Microencapsulated Electrophoretic Display, MED. The initial approach is to create tiny spheres, in which the charged color pigments are suspending in the transparent oil and would move depending on the electronic charge. The E-paper screen display patterns by reflecting the ambient light, so it has no background light requirement. Under ambient light, the E-paper screen still has high visibility with a wide viewing angle of 180 degrees. It is the ideal choice for E-reading.(Note that the e-Paper cannot support updating directly under sunlight)
How to use
Working with Windows PC
- Connect 10.3inch e-paper to IT8951 driver board as below
- Connect USB interface of IT8951 driver board to PC
- Download and open E-LINK-TCON-DEMO software
- Click connect as below
- Check option "AutoSet", then click "Open File" to open one picture for display. Browse diagram will be opened, and you should click "OK"
- Click "display" to refresh the picture
Working with Raspberry Pi
- Step 1:Insert IT8951 driver board to GPIO of Raspberry Pi, Connect e-Paper to the driver board
- You can also connecting by wires
IT8951 Driver HAT | Raspberry Pi (BCM) | Description' |
5V | 5V | 5V power input |
GND | GND | Ground |
MISO | P9 | MISO Pin of SPI |
MOSI | P10 | MOSI Pin of SPI |
SCK | P11 | SCK Pin of SPI |
CS | P8 | Chip selection of SPI (Low active) |
RST | P17 | Reset pin (Low active) |
HRDY | P24 | Busy stats pin (Low when busy) |
- Step 2: Make sure you have switched to SPI mode
- Step 3: Download and install BCM2835 librariesto your Raspberry Pi
- You can also download the newest bcm2835 library from its official website http://www.airspayce.com/mikem/bcm2835/
- Copy the library you download to Raspberry Pi and install it withe commands below. You can also following the instruction on its website above
tar zxvf bcm2835-1.xx.tar.gz cd bcm2835-1.xx ./configure make sudo make check sudo make install
- Step 4: Enable SPI
The Raspberry Pi uses SPI to drive the IT8951 and then drives the ink screen. First, you need to open the SPI. The way to open it is as follows:
Open a terminal command line and enter the command:
sudo raspi-config Then execute: Interfacing Options->P4->SPI->Yes, as shown in the following figure:
- Step 4: Download Demo codes of 10.3inch e-Paper HAT and test
git clone https://github.com/waveshare/IT8951-ePaper.git cd IT8951-ePaper/Raspberry sudo make clean sudo make -j4
- Check the VCOM data from the FPC
- Run the example and use the VCOM value as a parameter as well as number 0
sudo ./epd -2.51 0
- Expected result
- Display 16 gray bars in partial mode
- Draw figures and strings
- Display pictures in 1bp, 2bp, and 4bp modes
- Fast updating in A2 mode
- Display a gif
- Dispaly a demo for calculating the framerate
- Clear the display in Init mode
Working with STM32
Because IT8951 will cost big size of RAM, some of STM32 cannot support without external SDRAM device. So we here use Open429I as test board, Open429I integrates IS42S16400J (64-MBIT) SDRAM,has full memory to drive the 9.7inch e-paper.
Working with STM32, you can use SPI, I80 or I2C interface. SPI is simple and only a few of GPIOs are used, its speed can also meet the requirement of most applications. I80 is also simple and fast, however, it need to use lots of GPIO. I2C is every slow, which we don't recommend.
- SPI
1) Hardware connection
IT8951 | STM32 | Description |
5V | 5V | 5V Power input |
GND | GND | Ground |
MISO | PE13 | Data output |
MOSI | PE14 | Data input |
SCK | PE12 | Clock input |
CS | PE11 | Chip select (Low active) |
RST | PC5 | Reset (Low for reset) |
HRDY | PA7 | BUSY state output (Low for busy) |
2) Set the DIP switch to SPI mode
3) Download demo code and test
You can download the Demo code
Open the project with keil: Open429I-IT8951-Demo\Project\IT8951\MDK-ARM\Project.uvproj
Compile it, then open IT8951.h, check if SPI mode is enabled. Compile it again and download to your board.
After downloading, the information will be printed as below (115200, 8N1)
- I80
1) Hardware connection
IT8951 | STM32 | Description |
Vcc | 5V | 5V Power input |
GND | GND | Ground |
DBUS0~DBUS15 | PB0~PB15 | Data pins |
HWE | PC1 | Write enable (Low active) |
D/C | PC7 | Data/Command (Low for command) |
CSEL | PC6 | Chip select (Low active) |
HRD | PC3 | Read enable (Low for active) |
RST | PC0 | Reset (Low for reset) |
BUSY | PA7 | Busy state output (Low for busy) |
2) Set the DIP switch to I80 mode
3) Display with demo code
You can download the Demo code
Open the project with keil: Open429I-IT8951-Demo\Project\IT8951\MDK-ARM\Project.uvproj
Compile it, then open IT8951.h, check if I80 mode is enabled. Compile it again and download to your board.
Information are printed to serial port as below (115200, 8N1)
Display pictures
For easy porting our demo code, we display picture with data matrix instead of file system.
We should first convert BMP picture to data matrix (arrays), and use it in demo code.
1) Prepare a BMP image, resize the picture to 800*600
2) Open BMP convert software, Click File->Open..-> to open the picture as below:
3) Click Image -> Convert to ->Gray256(8 BPP)
4) Click File ->Save As... ->Choose "C" bitmap file (*.c) -> input file name and click Save.
5) Choose 8 bit per pixel, click OK. A C file will be saved to your PC
6) Add the C file to keil project, delect unusable information
********************************************************************* * SEGGER Microcontroller GmbH & Co. KG * * Solutions for real time microcontroller applications * * www.segger.com * ********************************************************************** * * * C-file generated by * * * * Bitmap Converter for emWin V5.22. * * Compiled Jul 4 2013, 12:18:24 * * (c) 1998 - 2013 Segger Microcontroller GmbH && Co. KG * * * ********************************************************************** * * * Source file: zoo_800_600 * * Dimensions: 800 * 600 * * NumColors: 256 * * * ********************************************************************** */ #include <stdlib.h> #include "GUI.h" #ifndef GUI_CONST_STORAGE #define GUI_CONST_STORAGE const #endif extern GUI_CONST_STORAGE GUI_BITMAP bmzoo_800_600; /********************************************************************* * * Palette * * Description * The following are the entries of the palette table. * The entries are stored as a 32-bit values of which 24 bits are * actually used according to the following bit mask: 0xBBGGRR * * The lower 8 bits represent the Red component. * The middle 8 bits represent the Green component. * The highest 8 bits represent the Blue component. */ static GUI_CONST_STORAGE GUI_COLOR _Colorszoo_800_600[] = { 0x000000, 0x010101, 0x020202, 0x030303, 0x040404, 0x050505, 0x060606, 0x070707, 0x080808, 0x090909, 0x0A0A0A, 0x0B0B0B, 0x0C0C0C, 0x0D0D0D, 0x0E0E0E, 0x0F0F0F, 0x101010, 0x111111, 0x121212, 0x131313, 0x141414, 0x151515, 0x161616, 0x171717, 0x181818, 0x191919, 0x1A1A1A, 0x1B1B1B, 0x1C1C1C, 0x1D1D1D, 0x1E1E1E, 0x1F1F1F, 0x202020, 0x212121, 0x222222, 0x232323, 0x242424, 0x252525, 0x262626, 0x272727, 0x282828, 0x292929, 0x2A2A2A, 0x2B2B2B, 0x2C2C2C, 0x2D2D2D, 0x2E2E2E, 0x2F2F2F, 0x303030, 0x313131, 0x323232, 0x333333, 0x343434, 0x353535, 0x363636, 0x373737, 0x383838, 0x393939, 0x3A3A3A, 0x3B3B3B, 0x3C3C3C, 0x3D3D3D, 0x3E3E3E, 0x3F3F3F, 0x404040, 0x414141, 0x424242, 0x434343, 0x444444, 0x454545, 0x464646, 0x474747, 0x484848, 0x494949, 0x4A4A4A, 0x4B4B4B, 0x4C4C4C, 0x4D4D4D, 0x4E4E4E, 0x4F4F4F, 0x505050, 0x515151, 0x525252, 0x535353, 0x545454, 0x555555, 0x565656, 0x575757, 0x585858, 0x595959, 0x5A5A5A, 0x5B5B5B, 0x5C5C5C, 0x5D5D5D, 0x5E5E5E, 0x5F5F5F, 0x606060, 0x616161, 0x626262, 0x636363, 0x646464, 0x656565, 0x666666, 0x676767, 0x686868, 0x696969, 0x6A6A6A, 0x6B6B6B, 0x6C6C6C, 0x6D6D6D, 0x6E6E6E, 0x6F6F6F, 0x707070, 0x717171, 0x727272, 0x737373, 0x747474, 0x757575, 0x767676, 0x777777, 0x787878, 0x797979, 0x7A7A7A, 0x7B7B7B, 0x7C7C7C, 0x7D7D7D, 0x7E7E7E, 0x7F7F7F, 0x808080, 0x818181, 0x828282, 0x838383, 0x848484, 0x858585, 0x868686, 0x878787, 0x888888, 0x898989, 0x8A8A8A, 0x8B8B8B, 0x8C8C8C, 0x8D8D8D, 0x8E8E8E, 0x8F8F8F, 0x909090, 0x919191, 0x929292, 0x939393, 0x949494, 0x959595, 0x969696, 0x979797, 0x989898, 0x999999, 0x9A9A9A, 0x9B9B9B, 0x9C9C9C, 0x9D9D9D, 0x9E9E9E, 0x9F9F9F, 0xA0A0A0, 0xA1A1A1, 0xA2A2A2, 0xA3A3A3, 0xA4A4A4, 0xA5A5A5, 0xA6A6A6, 0xA7A7A7, 0xA8A8A8, 0xA9A9A9, 0xAAAAAA, 0xABABAB, 0xACACAC, 0xADADAD, 0xAEAEAE, 0xAFAFAF, 0xB0B0B0, 0xB1B1B1, 0xB2B2B2, 0xB3B3B3, 0xB4B4B4, 0xB5B5B5, 0xB6B6B6, 0xB7B7B7, 0xB8B8B8, 0xB9B9B9, 0xBABABA, 0xBBBBBB, 0xBCBCBC, 0xBDBDBD, 0xBEBEBE, 0xBFBFBF, 0xC0C0C0, 0xC1C1C1, 0xC2C2C2, 0xC3C3C3, 0xC4C4C4, 0xC5C5C5, 0xC6C6C6, 0xC7C7C7, 0xC8C8C8, 0xC9C9C9, 0xCACACA, 0xCBCBCB, 0xCCCCCC, 0xCDCDCD, 0xCECECE, 0xCFCFCF, 0xD0D0D0, 0xD1D1D1, 0xD2D2D2, 0xD3D3D3, 0xD4D4D4, 0xD5D5D5, 0xD6D6D6, 0xD7D7D7, 0xD8D8D8, 0xD9D9D9, 0xDADADA, 0xDBDBDB, 0xDCDCDC, 0xDDDDDD, 0xDEDEDE, 0xDFDFDF, 0xE0E0E0, 0xE1E1E1, 0xE2E2E2, 0xE3E3E3, 0xE4E4E4, 0xE5E5E5, 0xE6E6E6, 0xE7E7E7, 0xE8E8E8, 0xE9E9E9, 0xEAEAEA, 0xEBEBEB, 0xECECEC, 0xEDEDED, 0xEEEEEE, 0xEFEFEF, 0xF0F0F0, 0xF1F1F1, 0xF2F2F2, 0xF3F3F3, 0xF4F4F4, 0xF5F5F5, 0xF6F6F6, 0xF7F7F7, 0xF8F8F8, 0xF9F9F9, 0xFAFAFA, 0xFBFBFB, 0xFCFCFC, 0xFDFDFD, 0xFEFEFE, 0xFFFFFF }; static GUI_CONST_STORAGE GUI_LOGPALETTE _Palzoo_800_600 = { 256, // Number of entries 0, // No transparency &_Colorszoo_800_600[0] }; GUI_CONST_STORAGE GUI_BITMAP bmzoo_800_600 = { 800, // xSize 600, // ySize 800, // BytesPerLine 8, // BitsPerPixel _aczoo_800_600, // Pointer to picture data (indices) &_Palzoo_800_600 // Pointer to palette };
7) Modify the codes
static GUI_CONST_STORAGE unsigned char _aczoo_800_600[] = {
to this one. (You can change the name of the array to every one you like)
const unsigned char zoo_800_600[] = {
8) Modify related codes in IT8951.C as below
extern const unsigned char zoo_800_600[]; void IT8951DisplayExample3() { IT8951LdImgInfo stLdImgInfo; IT8951AreaImgInfo stAreaImgInfo; TWord width = gstI80DevInfo.usPanelW; TWord high = gstI80DevInfo.usPanelH; TDWord i; for (i = 0;i < width*high;i++) { gpFrameBuf[i] = zoo_800_600[i]; } IT8951WaitForDisplayReady(); //Setting Load image information stLdImgInfo.ulStartFBAddr = (TDWord)gpFrameBuf; stLdImgInfo.usEndianType = IT8951_LDIMG_L_ENDIAN; stLdImgInfo.usPixelFormat = IT8951_8BPP; stLdImgInfo.usRotate = IT8951_ROTATE_0; stLdImgInfo.ulImgBufBaseAddr = gulImgBufAddr; //Set Load Area stAreaImgInfo.usX = 0; stAreaImgInfo.usY = 0; stAreaImgInfo.usWidth = width; stAreaImgInfo.usHeight = high; IT8951HostAreaPackedPixelWrite(&stLdImgInfo, &stAreaImgInfo);//Display function 2 IT8951DisplayArea(0,0, gstI80DevInfo.usPanelW, gstI80DevInfo.usPanelH, 2); }
【Note】Guides provided here are all about how to use the 7.8inch e-Paper HAT (D). If you have any question about how to modify and develope you own codes, please refer to resources of IT8951 #Resources
Resources
Schematic
Demo code
Datasheet
Software
FAQ
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2. Try changing the USB interface. It is recommended to use the USB interface on the back of the PC. Relatively speaking, the power supply current will be larger.
3. Turn the DIP switch to the end. During shipping, the DIP switches may be loosened, and the floating configuration pins cannot put the IT8951 into USB mode.
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If you fail to refresh, check whether the hard link is normal, use the USB port on the back of the PC (most of the USB ports on the front of the PC have weak power supply capability), and replace the e-paper test.
Note: Do not plug and unplug the e-paper with power on, otherwise the driver board and e-paper may be damaged.
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Support
If you require technical support, please go to the Support page and open a ticket.