mcufriend tft lcd shield library for sale

I have bought "MCUFRIEND" 2.8 tft touch lcd and controller printed on it shows "ILI9338". Example given in this library are not working except for the basic one and it don"t even work with touch examples. After searching on google found out that "MCUFRIEND_kbv" library for debug. When i run "diagnose_tft_support" it shows following output. Also added "Read reg" after first output. Please Help !!!

A while ago I bought this 2.4"" Inch TFT LCD Touch Display Shield for Arduino UNO, but only recently I came up with a project where I could make use of this piece of hardware.

It turned out that indeed the RGB packing function from the Adafruit library did not play well with that display, but shifting and OR"ing the bits only slightly different would do the trick.

Then, instead of calling the method tft.clor565, a call to the newly created function fixed_color565 made sure that images got displayed correctly from now on..

I have one of these TFT LCD shields, but mine is a ILI9335. It has taken me nearly 2 weeks to find a working Library and code for my 9335 driver and I am now setting about creating sketches based around my working Library.

Unfortunately most sellers of these shields (excluding good reputable companies) do not adivise of which Driver is onboard the shield and it becomes difficult to locate a working Library for the driver of the purchased shield.

If there is no Library specific to your 6767 Driver (and I must say I have not seen one in my searches for the 9335 Driver) then you may have to download as many different Libraries to locate a sketch that works for yours.

There are many tutorials on Arduino shields for 2.4 inch TFT LCD displays. In this road test I apply different tutorials to check the performance and issues of this specific shield: AZ-Delivery 2.4 inch TFT LCD display with resistive 4-wire touchscreen and an integrated SD card reader.AZ-Delivery 2.4 inch TFT LCD display.

TFT LCD is a variant of a liquid-crystal display (LCD) that uses thin-film-transistor (TFT) technology. That improves image quality, better contrast and addressability.

Depends on the needs of your project. Arduino UNO processor frequency is low. With the Arduino UNO full-color TFT LCDs are suitable to display simple data and commands. The TFT controller used cannot switch internal display RAM, so you can"t use the double buffer technique for animations but still you can only re-draw small sections of screen.

This module consumes most of the resources available in Arduino UNO. This is not a limitation of the module itself. In return, using a parallel interface allows you to quickly update the image. If you want to take advantage of all its functionality (LCD + touch screen + SD card), only pins 0 and 1 (RX and TX, respectively) and pin 19 (A5) remain unused. If the SD card is not used, pins 10, 11, 12 and 13 are additionally available. With a suitable layout, some SPI devices could be connected even if the SD card is used.

The PCB silkscreen indicates the main function of each pin, the labels are easy to read, although it does not show labels for the touch screen pins:Pin 9 - Touch X+ / LCD_D1

The SD card reader is very well located between the USB connector and the power connector, it does not touch either of them as it happens in other lcd tft shield modules and it is easily accessible to insert and remove the SD cards.

You can directly use the shield with any arduino uno. In this case we are using an Arduino UNO that exposes all the pins both on the header and on the board. In such a way that you do not need another shield to access the pins not used by the screen

ShieldCompatible with Arduino. 5V compatible, can be used with 3.3V or 5V logic. On-board 3.3 V (300mA LDO controller). The design is very well thought out and fits Arduino UNO perfectly.

If you want to take advantage of all its functionality (LCD + touch screen + SD card), only pins 0 and 1 (RX and TX, respectively) and pin 19 (A5) remain unused. If the SD card is not used, pins 10, 11, 12 and 13 are additionally available. With a suitable layout, some SPI devices could be connected even if the SD card is used.

The ILI9341 which can control each pixel with a small number of pins. The shield connects ILI9341"s data pins 0-7 to Arduino digital pins 2-8 (allowing parallel communication, not SPI). ILI"s RESET goes to pin to Arduino analog pin A4.CS (chip select) to A3. RS (CD command/data) to A2. WR and RD to A1 and A0.

Includes a resistive 4-wire touchscreen (touchpad). The touch screen is attached on the surface of the display. Touch screen needs two analog inputs and two digital outputs. It connects through 4 wires, which share arduino pins 8, 9, A2, A3 with the ILI9341 driver. So you can"t write to LCD display and read the touch screen in the same time. I. Driver chip is XPT2046.

The resistive touch screen does not appear to appreciably affect the optical characteristics. Works properly, It takes a little pressure with the stylus for it to respond like in old mobile phones. You notice how it sinks into the screen when you press with the stylus. The stylus that comes with the module makes it easy to use if your interface design uses small controls. Some touch screen libraries offer better accuracy by specifying the resistance of the touch screen in the X direction. Resistance can be easily measured with a multimeter by connecting the test leads to the LCD_D1 - X + and LCD_DS X- terminals. Touch is sensitive to pressure.

The SD card reader works well. Accessing the SD card with the functions available in the SD library included in the IDE version used does not present any problem. SD cards are recognized and can be written or deleted.

...find the drivers that work. Numerous reviews on here mention the MCUFRIEND.kbv library, which I used and it works fine. Note that you"ll also need the Adafruit GFX library installed, as well, since the MCUFRIEND library relies on it, plus the...

Numerous reviews on here mention the MCUFRIEND.kbv library, which I used and it works fine. Note that you"ll also need the Adafruit GFX library installed, as well, since the MCUFRIEND library relies on it, plus the Adafruit Touchscreen library if you want to be able to read touch. All can be installed from right inside the Arduino IDE, it"s not necessary to install a .zip from the Github site.

Once installed, it was relatively painless to get the demo file running on a MEGA2560, a Due and a Teensy 3.2 that"s on a Sparkfun Uno shield adapter in short order. It"s worth noting that getting the touchscreen calibration demo to work on a 32 bit board is a pain in the ass, so I used the MEGA to run the detection and calibration for the touchscreen pins, and the calibration works on both the Due and the Teensy - I"ve posted the calibration results for this board below.

One major issue: the LCD driver seems not to be ILI9341. After trying many libraries for Arduino I checked the web address on the back of LCD PCB, the mcufriend. From there I found a couple of links to library files for 2.4 inch LCD. The library which worked for my LCD is MCUFRIEND_kbv, but that is not all... the library has a sketch named "diagnose_TFT_support", which reported via terminal that the LCD chip ID is 0x9595, which means that the line "#define SUPPORT_8347D" must be uncommented in MCUFRIEND_kbv.cpp file in library folder (see mcufriend_how_to.txt file for explanation). Thats it, my LCD works, even the touch panel.

In our previously published article we talked about MCUFRIEND TFT Touch Screen. Arduino TFT Touch Screen Calculator is an Easy Example of Practical Deployment of Programmable Microcontroller From the Libraries. It is important to understand that this guide will only supply codes which may be buggy on different “models” of MCUFRIEND TFT Touch Screens. I named this article as “Part 1” for those bugs and no practical improvement of others codes. What code will work for me may not work for your same one (however you’ll not see a blank white screen) or you’ll see mirror image. Frankly, there is no question of circuit diagram for a shield with Arduino UNO. Simply snap on the shield on Arduino UNO.

Below code is for your understanding and matching with the examples from MCUFRIEND_KBV example libraries, it will only show the keys. This is how the keyboard is drawn, you can change the colors, tweak. void loop() is empty. The code actually not respond to touch, it is only for checking the keys :

If with the above code you see everything fine but digits mirrored, then possibly you have some slightly different hardware, you probably need to tweak the like tft.setRotation. You can perform Google search to fix it. It is not big matter.

Actually a cheap color display has lot of advantages over any other type displays. Monochrome graphic LCD display actually costs same. Other options of cheap display is Nokia 5110 Display (which is often reported by many users as buggy), standard 1602A LCD Display (which is an all purpose standard basic LCD display). Here is Getting Started Guide For Arduino TFT Touch Screen Shield Manufactured by MCUFRIEND. This is possibly the cheapest 2.4″ color display for Arduino. It costs around $8 to $10. MCUFriend is a China company and has an useless website. However, all over the web, there is huge support for this cheap display. The display works as intended. I purchased it from physical shop. It is a 2.4″ diagonal LCD TFT display, has white-LED backlight, resistive touchscreen, 240×320 resolution, has SPFD 5408 controller with built in video RAM buffer, has 8 bit digital interface and 4 control lines, it uses digital pins 5-13 and analog 0-3. there is a micro SD card reader.

For Arduino UNO, you are actually having digital pins 2, 3, analog 4, analog 5 unoccupied by the shield. If you do not use the SD card slot then digital pin 12 is also available. 3 digital pins and 2 analog pins should be good for most of the basic projects but for multiple sensors, the actual need will be towards Arduino Mega instead of Arduino UNO. This shield does work with Arduino Mega but sometime oddly behave (may be there is some other problem with my piece). I lack idea whether the micro SD card slot actually works.

Obviously as it is a shield, it is challenging to use the unoccupied pins. The easy trick is use to pass a single stranded wire. I read somewhere that it is possible to control the backlight by connecting a digital pin and transistor.

C:\Users\duhjoker\Documents\Arduino\libraries\TFT_ILI9340-master\TFT_ILI9340.cpp: In constructor "TFT_ILI9340::TFT_ILI9340(uint8_t, uint8_t, uint8_t)":

This note introduces a low-cost Thin Film Transistor (TFT) display to enhance the operation and usefulness of Liquid Crystal Display(LCD) devices. TFT technology controls the pixel element on the glass surface thereby greatly reducing image blurring and improving viewing angles.

The test board chosen for this exercise is the Elegoo Arduino UNO board from the corresponding Super Starter Kit. The kit already has several simple numeric and text displays. The TFT display may perhaps provide better ways to interact in applications.

The controller for the illustrated model of the TFT display is SSD1297.This information is important because the display (owing to its low cost and high popularity) has many different manufacturers who may not leverage the same controller instruction set. The specification of the controller in the coding exercises is examined in the Appendix section of this note.

Of course, the display can be mounted elsewhere and the pins connected to the Arduino directly or indirectly using, for example, a breadboard. Other components can then use the breadboard in lieu of a shield with custom connectors. Of course, without access to such anon-standard or readily available breadboard, it is impossible to illustrate this arrangement in this note.

The Examples folder for the library provides the starter files for the tests. If you are using a newer display you will need the updated libraries from the GitHub repository (see link in References below)and using the#definestatement to identify the display model.

The output from the diagnostic program, LCD_ID_reading.ino, is shown below:Read Registers on MCUFRIEND UNO shieldcontrollers either read as single 16-bite.g. the ID is at readReg(0)or as a sequence of 8-bit valuesin special locations (first is dummy)reg(0x0000) 97 97ID: ILI9320, ILI9325, ILI9335, ...reg(0x0004) 97 97 97 97Manufacturer IDreg(0x0009) 97 97 97 97 97Status Registerreg(0x000A) 97 97Get Power Modereg(0x000C) 97 97Get Pixel Formatreg(0x0061) 97 97RDID1 HX8347-Greg(0x0062) 97 97RDID2 HX8347-Greg(0x0063) 97 97RDID3 HX8347-Greg(0x0064) 97 97RDID1 HX8347-Areg(0x0065) 97 97RDID2 HX8347-Areg(0x0066) 97 97RDID3 HX8347-Areg(0x0067) 97 97RDID Himax HX8347-Areg(0x0070) 97 97Panel Himax HX8347-Areg(0x00A1) 97 97 97 97 97RD_DDB SSD1963reg(0x00B0) 97 97RGB Interface Signal Controlreg(0x00B4) 97 97Inversion Controlreg(0x00B6) 97 97 97 97 97Display Controlreg(0x00B7) 97 97Entry Mode Setreg(0x00BF) 97 97 97 97 97 97ILI9481, HX8357-Breg(0x00C0) 97 97 97 97 97 97 97 97 97Panel Controlreg(0x00C8) 97 97 97 97 97 97 97 97 97 97 97 97 97GAMMAreg(0x00CC) 97 97Panel Controlreg(0x00D0) 97 97 97Power Controlreg(0x00D2) 97 97 97 97 97NVM Readreg(0x00D3) 97 97 97 97ILI9341, ILI9488reg(0x00D4) 97 97 97 97Novatek IDreg(0x00DA) 97 97RDID1reg(0x00DB) 97 97RDID2reg(0x00DC) 97 97RDID3reg(0x00E0) 97 97 97 97 97 97 97 97 97 97 97 97 97 97 97 97GAMMA-Preg(0x00E1) 97 97 97 97 97 97 97 97 97 97 97 97 97 97 97 97GAMMA-Nreg(0x00EF) 97 97 97 97 97 97ILI9327reg(0x00F2) 97 97 97 97 97 97 97 97 97 97 97 97Adjust Control 2reg(0x00F6) 97 97 97 97Interface Control

Many thanks toDavidPrenticefor the display driver library and the guidance, support and advice during the tests for this display. I would have failed at the starting block without his generous assistance. He is an authority on the drivers for this class of displays.