2 4 tft lcd shield mcufriend brands

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 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

The controller is referenced as SSD1297 with ID=0x9797. This display requires the use of the following statement in the code prior to the invocation of other header files for the display. Please review the header files for the equivalent#define SUPPORT_1289

I wired it up correctly, checked and double checked my wiring, and installed a few test sketches to figure out what driver I was using. It reported back that I was using "0x9341", which matches what is printed on the back.

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.

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.

I bought four MCU Friend 3.5″ TFT shields.  And, unfortunately, they have spiraled me into a deep, dark place trying to figure out how to use them.  The the documentation consists of a sticker on the antistatic bag, a picture of the shield with a list of 5 different possible LCD drivers, a pinout, and a block of code that supposedly represents the startup code.  The unfortunate part is that none of these have been exactly right – they all have errors.  This article is a description of the journey to figuring out how to use them.

Here is a picture of the bag. (the QR code is a number “181024202132” which I thought might be a phone number but isn’t.  It also doesn’t match anything in google, so i’m not sure what it is.

It also has a picture which says the LCD has one of several different controllers (and after digging in I know for a fact that two of mine were made by Raydium and are not on the list)

And finally a table of pins.  Which is interesting as it lists 37 pins when the shield has no where near that number.  And it shows the shield as  16-bit interface which it isnt … and it shows some LEDs which aren’t there either.

I bought 4 different shields.  One came broken.  The other three are all different.  When you look at the boards there are two visibly different configurations

The first thing I did was try to use the MCUFRIEND_kbv library to see if the screens worked.  The first board identified as ID=0x9403 and did not work.  Apparently, the tool just spits out the ID if it doesn’t know it, which it did not.

One of the boards identified as ID=0x6814 worked perfectly, and one had a blue cast to all of the screens.  The crazy part is the two boards that identified as ID=0x6814 had different PCBs.  According to the comments in the MCUFRIEND_kbv.cpp ID=0x6814 is an RM68140 and ID=9403 is unknown.

Next, I started down the path of trying to figure out what the controllers were by using register reads.  David Prentice (the guy who wrote/maintains the MCU Friend_kbv Arduino library) has an absolute ton of responses on the Arduino forum trying to help people figure out what their shield is.  He asks them to post the register report from his example program LCD_ID_readnew which is included as an example in the library.

When you look at these LCD controllers they all have some variant of “Read ID” which responds with 1-6 bytes.  The basic idea of this program is to look at what bytes are returned to try to identify the controller.  Here is an example of what I got when I ran the LCD_ID_readnew program on my shields:

The key thing to see in this output is the register 0x04 which says 54,80,66 which identifies this as a Raydium RM68140 LCD controller.  Here is a snapshot from the data sheet.

Unfortunately, the next thing to notice is that Register 0xBF has reg(0x00BF) FF FF 68 14 00 FF.  The unfortunate part is that this register is not documented in the data sheet beyond this one reference:

Presumably the “68 14” corresponds to a Raydium 68140, but who knows?  When I posted this on the Arduino forum, David Prentice responded (David does yeoman’s labor helping people and should be Thanked for all of his pro-bono work and putting up with a bunch of really bad questions)

After digging some more, I decided that it is super ugly out there, as you find that there are a significant number of LCD controllers that are clones, copies, pirated etc… and that they all present themselves differently.  And, in hindsight I think that this is the reason that my ILI9341 from the previous article doesnt quite work correctly.

The next thing that I did was try out the startup code that MCUFriend_kbv generates.  I used the same technique from PSoC 6 + Segger EmWin + MCUFriend 2.4″ Part 1 and spit out the startup bytes.  Here they are:

At this point I have spent a frightening amount of time figuring out how these screens work.  Although it has been a good learning experience, I have generally decided that using unknown displays from China with LCD drivers of questionable origin is not worth the pain of trying to sort out the interface.  Beyond that:

Im new to Arduino myself but i do have the same screen which works perfect,your problem is probably that the TFT shield is shorting off the top off the arduino usb put something non conductive there and reset. if your still having trouble, try removing the shield and watch each pin as you insert it to make sure they are all inserted in the correct pins, LCD_02 should be in Dig pin 2.

We pass ISO900, ISO14001 and TS16949 certificates.Strict quality control Inspection is done in FOG==>LCM==>LCM+ RTP/CTP==> production online inspection ==>Q.C inspection==>aging test 4 hours with load in 60 ℃ special room (as option)==>OQC

2)When EOL happens,usually we will get notification from original manufacturer 3-6 months in advance. We prepare another LCD brand solution as replacement for you or recommend you to do last buy if your annual quantity is small or even tool up a new LCD panel if your annual quantity is big.

2)The material we are using are all A grade from formal channels,with strong anti-shock capacity, anti-high-temperature capacity, high reliability and very low rate of reject.

2) Chinese Holiday Reminder: During annual Chinese holidays, services from certain suppliers and carriers may be affected, and delivery for orders placed around the following times may be delayed by 3 - 7 days: Chinese New Year; Chinese National Day,etc.

This is Sainsmart 2.4 inch TFT LCD module with the TFT LCD shield kit for arduino enthusiasts.It includes one piece of 2.4 inch TFT LCD display and a TFT LCD shield for Arduino MEGA2560 (R3).We will provided you the whole document including the example project of arduino due with the kit. We will supply you the technical support after your purchase.

Voltage type: 5v or 3v voltage input voltage,input is selectable. Because TFT can only work under 3.3 V voltage, so when the input voltage VIN is 5V, need through the 3.3 V voltage regulator IC step down to 3.3V , when the input voltage of 3.3 V, you need to use the zero resistance make J2 short , is equivalent to not through the voltage regulator IC for module and power supply directly.(Click here)

It is 100% compatible with the normal MCU like ARM AVR PIC and 8051,especially on arduino family such as arduino due and arduino mega2560(R3).The module uses the LCD controller Chip SSD1963 with 5 inch LCD including the touchscreen.

The shield defines that all the the data transmit ports are PC1-PC8 and PC12-PC19,the controll pins are PD0-PD3.The perfect design could realize that the data transmits in high speed.The SPI interface is designed in the ISP header of arduino due so that the SPI transfer with DMA could be achieved in high speed with no drag.

mcufriend LCD Display module TFT 2.4 Inch Screen for Arduino UNO R3 Mega. The shield is fully assembled, tested and ready to go. No wiring, no soldering! Works best with any classic (UNO/Duemilanove/Diecimila). This shield does NOT work with the Mega but its going to be half the speed of the Uno-type boards because of the way the Mega rearranges all the pins (there is no way to get around this!) This shield is not Leonardo-compatible Description: Spice up your project with a beautiful large touchscreen display shield with built in microSD card connection. This TFT display is big (2.4" diagonal) bright (4 white-LED backlight) and colorful (18-bit 262,000 different shades)! 240x320 pixels with individual pixel control. It has way more resolution than a black and white 128x64 display. As a bonus, this display has a resistive touchscreen attached to it already, so you can detect finger presses anywhere on the screen. Technical Details: 2.4" diagonal LCD TFT display 240x320 resolution, 18-bit (262,000) color spfd5408 controller with built in video RAM buffer 8 bit digital interface, plus 4 control lines Uses digital pins 5-13 and analog 0-3. That means you can use digital pins 2, 3 and analog 4 and 5. Pin 12 is available if not using the microSD Works with any "328 or Mega (Leonardo not supported yet) 5V compatible! Use with 3.3V or 5V logic Onboard 3.3V 300mA LDO regulator 4 white LED backlight. On by default but you can connect the transistor to a digital pin for backlight control 4-wire resistive touch screen

Hi community, I"m trying to read the touch screen values of 2.4" TFT display with no success. The display visual tests are running successfully. I have written a small script based on "diagnose_touchpins" example, because I use Wemos Lolin32 board and the pins are different. Here is the code: