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RP2350-90 Series

Description

The RP2350-90 Series of Intelligent Display Modules, is designed and manufactured by 4D Systems.

These RP2350-90 modules are 9.0" use an RGB Interface between the RP2350B Processor, and the 800x480 resolution TFT LCD Displays. The displays are an TN TFT LCD.

Available in Non-Touch, Resistive Touch, Capacitive Touch, and Capacitive Touch with Cover Lens Bezel (CLB).

The RP2350B Processor makes available multiple GPIO which include UART, SPI, I2C, PWM and Analog functionality, while also serving interfaces for the LCD Touch screen, Quad SPI Flash, microSD Card, and Native USB-C.

The user interface to the RP2350-90 series is a 30-pin FPC/ZIF socket, designed for a 30-way 0.5mm pitch FFC cable, for easy and simple connection to an application or motherboard, or for connecting to accessory boards for a range of functionality advancements.

This series of boards is compatible with the 4D Systems Workshop5 IDE, utilising the Raspberry Pi Pico SDK and 4D Systems purpose built libraries, allowing a feature rich design and programming experience.

Any code designed and written to run on other 4D Systems display modules, such as modules featuring Goldelox, Picaso, Pixxi or Diablo16 Graphics Processors, are unfortunately not compatible with the RP2350-90 range due to being a totally different processor family. However, please contact 4D Systems Support Team for assistance if you are planning on migrating from a different 4D Systems display model, as there are some similarities between them - such as the graphics, however a majority of the coding will have to be adapted.

From a mechanical perspective, these RP2350-90 modules are physically the same mounting size as other 4D Systems uLCD 9" modules, such as the DIABLO uLCD-90D, uLCD-90DT, uLCD-90DCT and uLCD-90DCT-CLB, as well as the PIXXI-44 versions, uLCD-90P4, uLCD-90P4T, uLCD-90P4CT and uLCD-90P4CT-CLB. The only difference is the circuitry used. Overall thickness of these RP2350-90 modules are greater than the 4D Systems 9" products, due to the USB-C connector and coin cell battery holder for the RTC. Typically where ever a uLCD-90 module had been mounted, a RP2350-90 module could fit in the same location.

The RP2350-90 modules utilise the same PCB as the gen4-RP2350 modules (4.3" to 7.0"), however due to the form-factor it is not itself classed as a gen4 module. It is however compatible with gen4 connections, as it has the same 30-way FFC, so can connect to the gen4-RP2350 Breakout, just like the gen4-RP2350 based modules.

RP2350-90T - Front

RP2350-90T Front

RP2350-90T - Rear

RP2350-90T Rear

RP2350-90CT - Front

RP2350-90CT Front

RP2350-90CT - Rear

RP2350-90CT Rear

RP2350-90CT-CLB - Front

RP2350-90CT-CLB Front

RP2350-90CT-CLB - Rear

RP2350-90CT-CLB Rear

Features

  • Powerful RP2350 Processor by Raspberry Pi.
  • 800x480 resolution displays utilising RGB-565 colours.
  • TN TFT LCD display.
  • Available in Non-Touch, Resistive Touch, Capacitive Touch, and Capacitive Touch with Cover Lens Bezel (CLB).
  • 520 KiB (520 × 1024 bytes) of on-chip SRAM.
  • 16MB of External Quad SPI Flash.
  • 8MB of External Quad SPI PSRAM.
  • 16 Configurable GPIO all able to of digital input and output or the following:
    • 5 GPIO capable of ADC (analog read)
    • Capable of UART (up to 2 Channels)
    • Capable of SPI (up to 2 Channels)
    • Capable of I2C (up to 2 Channels, 1 of which is utilized when using CTP variants)
    • and other RP2350 supported IO functions.
  • 30pin FPC connection, for all signals, power, communications, and GPIO.
  • Latch-type micro-SD memory card connector for multimedia storage and data logging purposes.
  • Display full colour images, animations, icons and video clips.
  • 4.0V to 6.0V range operation (single supply).
  • 4x metal mounting tabs built into the LCD, with 4.2mm holes for mechanical mounting using M4 screws (non CLB models only).
  • 3M Adhesive around perimeter of Cover Lens Bezel for mounting the CTP-CLB model.
  • RoHS and REACH compliant.
  • CE/EMC and UKCA compliance pending.
  • PCB is UL 94V-0 Flammability Rated.
  • Module dimensions:
    • (9.0" non-Touch): 230.7 x 126.4 x 12.2mm
    • (9.0" Resistive Touch): 230.7 x 126.4 x 13.7mm
    • (9.0" Capacitive Touch): 230.7 x 126.4 x 14.3mm
    • (9.0" Capacitive Touch w/ CLB): 235.0 x 148.7 x 14.3mm
  • Weighing (approximately):
    • (9.0" non-Touch): ~ 204g
    • (9.0" Resistive Touch): ~ 285g
    • (9.0" Capacitive Touch): ~ 290g
    • (9.0" Capacitive Touch w/ CLB): ~ 307g

Hardware Overview

Hardware Overview

Hardware Layout (9.0" CTP Module depicted)

Pin Symbol I/O Description
1 GND P Supply Ground
2 GPIO16 I/O General Purpose Input/Output pin, 3.3V logic
3 GPIO9 I/O General Purpose Input/Output pin, 3.3V logic
4 GPIO8 I/O General Purpose Input/Output pin, 3.3V logic
5 GPIO7 I/O General Purpose Input/Output pin, 3.3V logic
6 GPIO6 I/O General Purpose Input/Output pin, 3.3V logic
7 GPIO3 I/O General Purpose Input/Output pin, 3.3V logic
8 GPIO2 I/O General Purpose Input/Output pin, 3.3V logic
9 GPIO1 I/O General Purpose Input/Output pin, 3.3V logic
10 GPIO40 I/O General Purpose Input/Output pin, 3.3V logic
11 GPIO41 I/O/A General Purpose Input/Output pin capable of Analog, 3.3V logic
12 GPIO42 I/O/A General Purpose Input/Output pin capable of Analog, 3.3V logic
13 GPIO43 I/O/A General Purpose Input/Output pin capable of Analog, 3.3V logic
14 GPIO44 I/O/A General Purpose Input/Output pin capable of Analog, 3.3V logic
15 GPIO45 I/O/A General Purpose Input/Output pin capable of Analog, 3.3V logic
16 SPARE1 - Not connected
17 SPARE2 - Not connected
18 SWCLK I Access to the internal Serial Wire Debug multi-drop bus. Provides debug access to both processors, and can be used to download code.
19 SWD I/O Access to the internal Serial Wire Debug multi-drop bus. Provides debug access to both processors, and can be used to download code.
20 3.3V P 3.3V Output for User, connected to system 3.3V bus. Excessive draw will affect system stability. 100mA-200mA draw should be OK
21 GND P Supply Ground
22 RUN/RESET I Master Reset/Enable signal. Low will disable the chip, High will activate the chip.
23 UART-RX1 I Asynchronous Serial Receive pin, 3.3V TTL level. Connect this pin to the Transmit (Tx) signal of other serial devices. This pin is 3.3V Logic only. (GPIO5)
24 UART-TX1 O Asynchronous Serial Transmit pin, 3.3V TTL level. Connect this pin to the Receive (Rx) signal of other serial devices. This pin is 3.3V Logic only. (GPIO4)
25 GND P Supply Ground
26 5V IN P Main Voltage Supply +ve input pin. Reverse polarity protected. The range is 4.0V to 6.0V, nominal 5.0V.
27 5V IN P Main Voltage Supply +ve input pin. Reverse polarity protected. The range is 4.0V to 6.0V, nominal 5.0V.
28 5V IN P Main Voltage Supply +ve input pin. Reverse polarity protected. The range is 4.0V to 6.0V, nominal 5.0V.
29 5V IN P Main Voltage Supply +ve input pin. Reverse polarity protected. The range is 4.0V to 6.0V, nominal 5.0V.
30 GND P Supply Ground

Note

  1. I = Input, O = Output, P = Power, A = Analog Input
  2. It is recommended to connect at least 2 or more 5V IN pins to a stable 5V DC power supply, as well as at least 2 or more GND pins, especially important for the 7" display.
  3. Please refer to the Raspberry Pi RP2350B datasheet for specific detail on the capability of the RP2350 GPIO, in conjunction with the schematic of this module.

Hardware Interface - Pins

This section describes in detail the hardware interface pins of the module.

Serial Ports - 3.3V TTL

The RP2350-90 Series is configured to use the GPIO5 (RX) and GPIO4 (TX) as the default UART pins. These pins are broken out to the 30-way FFC connector through pins 23 and 24. This configuration uses UART1 of the RP2350B. However, it is possible to utilize other pins for UART1. Depending on pin availability, an additional UART bus can also be configured by utilizing UART0.

CTS and RTS pins can also be configured to work with the TX and RX pins. For instance, when using the default UART TX (GPIO4) and RX (GPIO5) in UART1, GPIO6 and GPIO7 can be used as CTS and RTS pins respectively. Other pins may be used as well as long as they share the same UART instance.

Please refer to the Raspberry Pi RP2350 Datasheet for more details.

I2C Port - 3.3V TTL

The RP2350-90 Series is configured to use GPIO9 (SCL) and GPIO8 (SDA) as the default I2C pins. These pins are broken out to the 30-way FFC connector through pins 3 and 4. External pull-up resistors may be required. This configuration uses I2C0 of the RP2350B.

It is not required to stick to this configuration. Other pins broken out of the 30-way interface can be used as alternative I2C pins.

Please refer to the Raspberry Pi RP2350 Datasheet for more details.

Note

When using capacitive touch variants of this series, I2C1 is being used to communicate with the touch chip. Therefore, the pins broken out of the 30-way interface and capable of I2C1 may not be used in this configuration. However, it is perfectly fine when using non-touch and resistive variants.

SPI Port - 3.3V TTL

The RP2350-90 Series is configured to use the following pins as the default SPI bus:

Pin Function
GPIO42 SCK
GPIO43 TX
GPIO44 RX
GPIO45 CSn

These pins are broken out to the 30-way FFC connector through pins 12 to 15. This configuration uses SPI1 of the RP2350B.

It is not required to stick to this configuration. Other pins broken out of the 30-way interface can be used as alternative SPI pins.

Please refer to the Raspberry Pi RP2350 Datasheet for more details.

General Purpose I/O

There are 16 general-purpose Input/Output (GPIO) pins available to the user. Many of these can be configured to be SPI, I2C and UART, amongst other configurations. Please refer to the Raspberry Pi RP2350 datasheet for more specific information.

GPIO Digital Input Digital Output Analog Read SPI I2C PWM UART
GPIO1 Yes Yes CSn0 SCL0 PWM0 B RX0
GPIO2 Yes Yes SCK0 SDA1 PWM1 A CTS0 / TX0
GPIO3 Yes Yes TX0 SCL1 PWM1 B RTS0 / RX0
GPIO4 Yes Yes RX0 SDA0 PWM2 A TX1*
GPIO5 Yes Yes CSn0 SCL0 PWM2 B RX1*
GPIO6 Yes Yes SCK0 SDA1 PWM3 A CTS1 / TX1
GPIO7 Yes Yes TX0 SCL1 PWM3 B RTS1 / RX1
GPIO8 Yes Yes RX1 SDA0* PWM4 A TX1
GPIO9 Yes Yes CSn1 SCL0* PWM4 B RX1
GPIO16 Yes Yes RX0 SDA0 PWM0 A TX0
GPIO40 Yes Yes RX1 SDA0 PWM8 A TX1
GPIO41 Yes Yes Yes CSn1 SCL0 PWM8 B RX1
GPIO42 Yes Yes Yes SCK1* SDA1 PWM9 A CTS1 / TX1
GPIO43 Yes Yes Yes TX1* SCL1 PWM9 B RTS1 / RX1
GPIO44 Yes Yes Yes RX1* SDA0 PWM10 A TX0
GPIO45 Yes Yes Yes CSn1* SCL0 PWM10 B RX0
  1. Functions marked with * are default configuration specified for the boards configuration in the Pico SDK.
  2. All pins broken out of the FFC interface is capable of PIO. However, please note that the LCD requires to use PIO. The uSD interface on the other hand is recommended to utilize PIO for SDIO but may also be interfaced through SPI. When using the Graphics4D library, both the LCD interface and the SD card utilizes PIO.

Please refer to the Raspberry Pi RP2350 datasheet for complete GPIO capabilities and Pico SDK documentation for information on how to configure the GPIO for various functions: digital input and output, analog input, I2C, UART and SPI, etc.

GPIO1 to GPIO9, and GPIO16

General purpose I/O pin, capable of Digital Input and Output. This pin is 3.3V tolerant only and 3.3V logic level. Can be configured for additional functionality such as SPI, I2C, UART etc. - please refer to the Pico SDK documentation.

GPIO40 to GPIO45

General purpose I/O pin, capable of Digital Input and Output, along with Analog Input. This pin is 3.3V tolerant only and 3.3V logic level. Can be configured for additional functionality such as SPI, I2C, UART etc. - please refer to the Pico SDK documentation.

System Pins

5V IN (Module Voltage Input):

Module supply voltage input pins. At least two (however ideally four) of these pins should be connected to a stable supply voltage in the range of 4.0 Volts to 5.5 Volts DC. Nominal operating voltage is 5.0 Volts. Utilising 4 pins shares the current over the FFC cable, which is important for the larger size displays.

GND (Module Ground):

Device ground pins. At least two (ideally four) pins should be connected to the ground.

RUN/RESET (Module Run/Reset):

Pulling this pin to 0V will disable the module, and put it into a reset state. Pulling the pin High or floating (due to build in pull-up resistor) will enable the module.

Module Features

The RP2350-90 Series is designed to accommodate a wide variety of applications. Some of the main features of the module are listed below.

RP2350B Processor

The module is designed around the RP2350B Processor from Raspberry Pi. This model of RP2350 has 48 GPIO in total, most of which are used to connected to the display and microSD. The rest of the pins are broken out of the modules FFC interface for the user.

The RP2350 chip doesn't have an internal flash and is instead connected to an external 16MB Quad SPI Flash for application storage. It features 520 KiB (520 x 1024 bytes) on-chip SRAM and a 1MB external Quad SPI PSRAM. Both the external Flash and PSRAM are connected via the XIP interface with the PSRAM utilizing GPIO0 for XIP CS1 pin.

Media is typically stored on a micro-SD card, however some types of media can be stored in SPI Flash, however it is very limited for capacity.

Chipsets used

The RP2350-90 Series of modules utilises a few chipsets from various manufacturers, in order for these modules to operate. Please refer to the Schematic for connection details.

  • The main processor is an Raspberry Pi RP2350B, as mentioned in the previous section.
  • For Capacitive Touch models, the chipset for the capacitive touch is I2C driven, and the chipset is found on the Display flex itself. These utilise Focaltech FT5446 controllers.
  • For Resistive Touch models, the chipset used is the NSIWAY NS2009 Resistive Touch driver, which is a 4-wire controller, and is I2C driven.
  • The Quad SPI Flash memory used on these modules, is the Winbond W25Q128JVSIQ, which is 16MB in capacity, and interfaces to the RP2350B on the same Quad SPI bus as the PSRAM.
  • The Quad SPI PSRAM used on these modules, is a AP Memory APS6404L-3SQR-SN, which is 8MB in capacity, and interfaces to the RP2350B on the same Quad SPI bus as the Flash memory.
  • The micro-SD card interface, while not a chipset, is still worthy of note. It utilises several GPIO pins from the RP2350 serving as an SDIO bus through PIO. The micro-SD cards can also be used with SPI but is much slower but frees up extra PIO.

SD/SDHC Memory Cards

The RP2350-90 modules use off-the-shelf standard SDHC/SD/microSD memory cards with up to 4GB capacity usable with FAT16 formatting, and much higher with FAT32 formatting. For any FAT file-related operations, before the memory card can be used it must first be formatted. The formatting of the card can be done on any PC system with a card reader.

Cards with a FAT16 formatting (4GB or under partition) are capable of operating faster on this display module, compared to the same card (16GB for example) with a single FAT32 partition, due to the nature of FAT16 vs FAT32 file transfers. If your application media can fit inside a 4GB partition, it is recommended to use FAT16 to gain the maximal speed possible.

SD Card

RMPET, a 4D Systems Tool found in the Workshop5 IDE, is capable of repartitioning and formatting microSD cards for FAT16, to be the appropriate type and format. This tool should be used for all cards as it also employs an offset which is critical when using Industrial microSD cards which feature Read Disturb Prevention firmware, which is a special firmware inside the microSD card designed to prevent Read Disturb occurring on NAND based Flash media. Further discussed in the note.

Note

  1. An SPI Compatible SDHC/SD/microSD card MUST be used when operating in SPI mode instead of SDIO via PIO. If a non-SPI compatible SD card is used, then the processor should utilize PIO to behave as an SDIO interface.
  2. Read disturbance is a well-known issue with flash memory devices, such as microSD cards, where reading data from a flash cell can cause the nearby cells in the same memory block to change over time. This issue can be prevented by using industrial-grade microSD cards with read disturb protection. Industrial-grade microSD cards have firmware that actively monitors the read operation and refreshes areas of memory that have high traffic and even move data around to prevent read disturb error from occurring. Furthermore, manufacturers may choose to implement read disturb protection on a specific part of the flash memory only, such that the beginning part of the memory might not be protected. The RMPET utility in Workshop5 is designed to create the first partition at an offset from the start of the microSD card to account for this situation. It is therefore recommended to always partition and format an industrial microSD card using the RMPET utility before using it with 4D Systems modules. Many commercial grade cards designed for Cameras etc, do not handle read disturb well at all, and therefore it is always recommended to use an Industrial grade microSD card with 4D modules. 4D offers one that is tried and tested, on our website.

microSD Socket Usage

On the RP2350-90 modules is a Latch-Type microSD socket. To use this socket is simple if you follow these easy steps.

  • Unlock the empty socket by sliding/unlocking the socket towards the edge of the PCB (away from the battery holder).
  • Lifting the lid of the socket, and hinging it up off the PCB, towards the edge of the module.
  • Placing a microSD card into the socket.
  • Lowering the lid of the socket back down, by hinging it down towards the PCB again.
  • Locking the socket back in place by sliding/locking the socket towards the battery holder.

Below is an illustration of the Latch-Type microSD socket. A gen4-RP2350-43T module is illustrated, however the operation is identical for the RP2350-90 product range.

Please refer to the following animation for guidance:

Please refer to the following diagram for guidance:

Video Player

Sequence

FAT16 vs FAT32

FAT16 is capable of having a partition with up to 4GB capacity usable. While this might seem like a limitation, it still offers the best performance for small processor systems such as the RP2350. Larger partitions are possible with FAT32 formatting, however smaller cluster size results, giving slightly worse performance.

For any FAT file-related operations, before the memory card can be used it must first be formatted correctly. Built into Workshop5 is a tool created by 4D, called RMPET (please refer to the Tools menu, inside the Workshop5 IDE). RMPET allows the User to easily partition and format microSD cards, to make their file system ready to be used with 4D Systems modules. The formatting of the card can be done on any Windows PC system with a card reader.

BOOTSEL and RESET Buttons

The gen4-RP2350 series of display modules features two onboard buttons that allow manually resetting to bootloader mode. This allows the display module to be easily programmable by copying UF2 files to the USB drive that appears while in bootloader mode.

To reset into bootloader mode, perform the following:

  1. Press and hold the BOOTSEL button.
  2. Briefly press the RESET button to reset the display.
  3. Release the BOOTSEL button.

Typically, one doesn't always need to manually trigger bootloader mode using these buttons. It is possible to reset the display into bootloader mode when USB Serial is set up in the last project uploaded to it. Workshop5 IDE uses this feature to effective upload programs to the display without the user having to manually putting it to bootloader mode.

For more information regarding programming the gen4-RP2350 modules using Workshop5, please refer to Workshop5 RP2350 Environment Manual

Display/Module Precautions

  • Avoid having to display the same image/object on the screen for lengthy periods. This can cause a burn-in which is a common problem with all types of display technologies. Blank the screen after a while or dim it very low by adjusting the contrast. Better still; implement a screen saver feature.
  • Moisture and water can damage the display. Moisture on the surface of a powered display should not cause any problems, however, if water is to enter the display either from the front or from the rear, or come in contact with the PCB, it will damage. Wipe off any moisture gently or let the display dry before usage. If using this display module in an environment where it can get wet, ensure an appropriate enclosure is used.
  • Dirt from fingerprint oil and fat can easily stain the surface of the display. Gently wipe off any stains with a soft lint-free cloth.
  • The performance of the display will degrade under high temperatures and humidity. Avoid such conditions when storing.
  • Do not tamper with the display flex cable that is connected to the control board. This may affect the connection between the display and the driving circuitry and cause failure.
  • Displays are susceptible to mechanical shock and any force exerted on the module may result in deformed zebra stripes, a cracked display cell and a broken backlight.
  • Always use the mounting holes on the module's to mount the display where possible, or mount using the CLB for CLB based modules.
  • Display modules have a finite life, which is typically dictated by the display itself, more specifically the backlight. The backlight contains LEDs, which fade over time. In the Specifications section is a figure for the typical life of the display, and the criteria are listed.
  • The resistive Touch model features a touch-sensitive film over the display which is sensitive to pressure. When mounting the display module in an enclosure, you should not apply pressure to the surface of the display by the enclosure. It could result in false touches or the touch will simply not function at all.

Hardware Tools

The following hardware tools are required for full control of the RP2350-90 Display Modules.

gen4-RP2350 Breakout Board

The gen4-RP2350 Breakout provides easy access to the pins broken out of the 30-way FFC. The board is designed to be compatible with breadboards making it perfect for prototyping.

It also provides direct access to the Serial Wire Debug (SWD) port both through JST connection or through the signals broken out of the sides, making it compatible with Raspberry Pi Debug Probe. In addition to this, the default UART pins are also marked making it easy to connect the UART pins of the debug probe for simple UART debugging. The default I2C and SPI pins are also labeled for ease of use.

The diagrams shown above serves as a reference showing how the 30-way FFC cable connects to the RP2350 module and the breakout board. The connectors on both the RP2350 module, and the breakout board, are Top-Contact, meaning the FFC cable pins should be facing upwards, and the blue stiffener, should be facing down towards the PCB.

Note

If using the gen4-RP2350 breakout, only the supplied FFC cable (or same type) can be used. The type of cable supplied, as described in the FFC Cable section, is an Opposite type (contacts on opposite sides to each other at end end). If a straight cable (contacts on the same side at both ends) is sourced, this will NOT work when connecting to the gen4-RP2350 breakout, as the connections will be swapped. Please refer to the information provided for more detail.

4D-UPA

The 4D-UPA is NOT designed to be able to upload applications to the RP2350 modules. However, it can be used to as a simple UART debugger and breakout the GPIO of RP2350 at the same time. This can be useful for development and testing or final product use in cases where another host needs to communicate with the display using USB connection but needs to keep the main USB-C port for programming.

The GPIO naming convention on the 4D-UPA does not reflect the GPIO naming of the actual display module, due to the 4D-UPA being universal and able to be used with many 4D Products. Please review the 4D-UPA schematic diagram for information on mapping the GPIO naming from this module, with the GPIO naming on the 4D-UPA, to ensure you connect to the correct pins you desire.

4D-UPA is NOT required for programming the RP2350-90 series of modules, as they have USB-C on board. It is only suitable for simple UART debugging and specific use cases as mentioned previously.

The connectors on both the RP2350 module, and the 4D-UPA, are Top-Contact, meaning the FFC cable pins should be facing upwards, and the blue stiffener, should be facing down towards the PCB.

Note

If using the 4D-UPA, only the supplied FFC cable (or same type) can be used. The type of cable supplied, as described in the FFC Cable section, is an Opposite type (contacts on opposite sides to each other at end end). If a straight cable (contacts on the same side at both ends) is sourced, this will NOT work when connecting to the 4D-UPA, as the connections will be swapped. Please refer to the information provided for more detail.

USB-C Cable

A USB-C Cable is the primary way to program a RP2350-90 module from 4D Systems, as described previously.

A USB-C cable is not supplied with the modules, as they can be sourced from any computer or hardware store, and come with most Cell Phones these days too.

Connection of the USB-C cable to the module is simple, and simply plugs into the USB-C connector on the board.

The USB-C provides power as well as USB Data communications while developing software on the module and programming it. The USB-C cable can be used in the end product use if desired, or the use of the FFC-Cable directly to the projects main Application PCB as an alternative.

USB-C Connection

USB-C Connection

Workshop5 IDE

Workshop5 is a new comprehensive software IDE, designed based on Workshop4, that provides an integrated software development platform for all the 4D family of processors and modules, as well as some 3rd party processors such as the Raspberry Pi RP2350.

The IDE provides a code editor and WYSIWYG design area for RP2350 based modules, to develop complete application code with various widgets and media references as required.

All user application code can be developed within the Workshop5 IDE, and is easily coupled with graphics and media, so it can be a one-stop shop for development with these modules.

The Workshop5 IDE utilises the Pico SDK to handle the compiling, linking and downloading of RP2350 based projects, without having to interface with any separate application at all.

For experienced users who may prefer or need to use some features that other software provides, Workshop5 provides a way to export the project to a simple standalone project that can be opened in VS Code or similar applications allowing users to continue their development in their preferred software tools.

Note

Pico SDK needs to be installed together with all its dependencies before Workshop5 can compile and upload projects. These are not included when installing Workshop5 and must be installed separately using the pico-setup-windows installer.

For complete development setup instructions, please refer to the Workshop5 RP2350 Development Manual

Built-in Tools

Built into Workshop5 are a number of tools which are available to aid the programming of the RP2350-90 series of displays.

Terminal, as the name implies, is a terminal application that can be used to communicate with the display module and is primarily used for basic debugging. It displays incoming Serial messages from the display module in ASCII and HEX format. It is capable of sending character or hex strings as well as keystrokes to the display.

RMPET is a partitioning and formatting tool, used to correctly set up a micro-SD card for use with 4D Systems products. This is further discussed in the SD/SDHC Memory Cards section

Programming Language

The programming language used in the Workshop5 IDE to program the RP2350 series of modules, is C++. It simplifies microcontroller coding, bridging the gap between users and hardware. Its approachability and community support make it ideal for various projects.

Display Module Part Numbers

The following is a breakdown of the part numbers and what they mean.

Examples:

  • RP2350-90
  • RP2350-90T
  • RP2350-90CT
  • RP2350-90CT-CLB

Example Starter Kits

  • SK-RP2350-90T
  • SK-RP2350-90CT

where:

SK     - Starter Kit (kitting of multiple parts)
RP2350 - RP2350 Display Family
90     - Display size (9.0")
T      - Resistive Touch
CT     - Capacitive Touch
CLB    - Cover Lens Bezel

Note

  • The SK at the start denotes it’s a Starter Kit, and the rest of the part number describes the display module in the Starter Kit.
  • A product without a T or CT in the part number is a non-touch variant.
  • Cover Lens Bezels (CLB) are glass fronts for the display module with overhanging edges, which allow the display module to be mounted directly into a panel using special adhesive on the overhanging glass. This is available for capacitive touch only.
  • Resistive Touch models are not available in CLB, as a CLB is made of glass and resistive touch relies on the mechanical flexing of a membrane to trigger touch.

Cover Lens Bezel - Tape Spec

The perimeter of the CLB display modules features double-sided adhesive tape, designed to stick directly onto a panel, enclosure, box etc. without the need for any mounting screws or hardware.

RP2350-90CT-CLB Tape View

The tape used is 3M 9495LE tape, which uses well-known and strong 3M 300LSE adhesives. The double-sided adhesive has a thickness of 0.175mm once the backing has been removed.

More information on this adhesive can be found on the 3M website.

FFC Cable

The FFC cables supplied by 4D Systems (included with products) have the following specifications:

  • 30 Pin Flexible Flat Cable, 150mm Long, 0.5mm (0.02") pitch
  • Cable Type: AWM 20624 80C 60V VW-1
  • Heat Resistance 80 Degrees Celsius
  • Connections on the opposite side at each end (Type B)

You can get different cable lengths from the 4D Systems website.

FFC Cable

Note

If you are interfacing with this module directly to your product via the 30-way FFC rather than utilising a breakout board or 4D-UPA, suitable connectors are readily available from many electronics suppliers, such as Digikey, Mouser, Farnell, RS, etc.

A standard 30-pin, 0.5mm pitch, 0.3mm thick FFC, FFC connector. They are available in Top Contact and Bottom Contact, so depending how you orientate the cable on your product, will determine which one you need. Please however take care of the pinout and how it flows from the display module, through the FFC and into your product, to ensure Pin1 and Pin30 are where you expect them to be.

Starter Kit

4D Systems highly recommends all first-time buyers of 4D Systems’ displays, to purchase the Starter Kit when purchasing their first 4D Systems display solution.

The Starter Kit provides all the hardware that is required to get the User up and running.

Starter Kits typically include:

  • RP2350-90 Series Display Module
  • gen4-RP2350 Breakout Board
  • 4GB micro-SD Card
  • 150mm 30-way FFC cable for connecting display to gen4-RP2350 Breakout, 4D-UPA, or Users System

Please refer to the 4D Systems website for the current components included in the Starter Kit.

Simply select the Starter Kit option when purchasing the chosen display module on the 4D Systems shopping cart, or from your local distributor.

Mechanical Details

Non-Touch, Resistive and Capacitive

RP2350-90 / 90T / 90CT Mechanical Drawing

Capacitive w/ CLB

RP2350-90CT-CLB Mechanical Drawing

Schematic Circuit Details

RP2350-90 Schematic

Specifications

Absolute Maximum Ratings

Operating ambient temperature -20°C to +65°C (see note 1)
Storage temperature -30°C to +80°C
Voltage on any digital input pin (RP2350) with respect to GND -0.3V to 3.6V
Voltage on any digital input pin (IO Expander) with respect to GND -0.3V to 6.0V
Voltage on VCC with respect to GND -0.3V to 6.5V

Note

  1. Temperature range for Ambient and Storage, are determined by a combination of components used on these modules. While some components may be capable of exceeding these temperatures, some are not, so the minimums/maximums are determined by the weakest device on the modules. The 'weakest' component on the module is the TFT LCD, which is capable of -20°C to 70°C Operating Temp.

  2. Stresses above those listed here may cause permanent damage to the device. This is for stress rating only and functional operation of the device at those or any other conditions above those indicated in the recommended operation listings of this specification is not implied. Exposure to maximum rating conditions for extended periods may affect device reliability.

Recommended Operating Conditions

Parameter Conditions Min Typ Max Units
Supply Voltage (VCC) Stable external supply required 4.0 5.0 6.0 V
Processor voltage (VP) -- 3.3 -- V
Input Low Voltage (VIL) all pins 0 -- 0.25VP V
Input High Voltage (VIH) non 5V tolerant pins 0.75VP -- VP+0.3 V
Input High Voltage (VIH) 5V tolerant pins 0.8VP -- 5.5 V

Global Characteristics Based on Operating Conditions

Parameter Conditions Min Typ Max Units
Supply Current (ICC) *** RP2350-90 (Contrast = 15) -- 810 -- mA
RP2350-90T (Contrast = 15) -- 815 -- mA
RP2350-90CT (Contrast = 15) -- 820 -- mA
RP2350-90CT-CLB (Contrast = 15) -- 820 -- mA
Display Endurance Hours of operation, measured to when display is 50% original brightness 30000 -- -- H
Touch Screen Endurance (Resistive Touch) Number of touches/hits with a 12.5mm tip at a rate of 2x per second with 250gf force -- 1M -- Touches
Slide stylus on screen, 100gf force, 60mm/s speed with a 0.8mm polyacetal tip stylus pen -- 100K -- Slides
Touch Screen Transparency Resistive Touch 82 -- -- %
Capacitive Touch 90 -- -- %
Touch Screen Operational Force (Resistive Touch) Only use Finger or Stylus, do not use anything sharp or metal 20 -- 100 Gf
CLB Hardness Cover Lens Bezel Glass Hardness -- 6 -- H

Note

Typical Supply Current (ICC) figures are without microSD card inserted, and using simple display operations only. Any additional load such as GPIO sourcing etc, will increase this figure. This is a Typical figure only, not a Maximum.

LCD DISPLAY INFORMATION (TN DISPLAY)

Parameter Conditions Specification
Display Type TN - TFT Transmissive LCD
Display Size 9.0" Diagonal
Display Resolution 800 x 480 (Landscape/Wide Viewing)
Display Brightness RP2350-90 (Contrast = 15) 500 cd/m2
RP2350-90T (Contrast = 15) 400 cd/m2
RP2350-90CT (Contrast = 15) 475 cd/m2
RP2350-90CT-CLB (Contrast = 15) 475 cd/m2
Display Contrast Ratio Typical 500:1
Display Viewing Angles Above Centre 50 Degrees
Below Centre 70 Degrees
Left of Centre 70 Degrees
Right of Centre 70 Degrees
Display Viewing Direction 6 O'clock Display (Optimal viewing is from below when in Landscape/Wide mode)
Display Backlighting All 9.0" models 11x3 Parallel LED's
Pixel Pitch Width x Height – Landscape 0.2475 x 0.2327mm (non-Square pixels)
Pixel Density Number of pixels in 1 row in 25.4mm, 7.0" 103 DPI/PPI (Horizontal)
109 DPI/PPI (Vertical)

Note

Relevant for all displays, the Displays used are of the highest rated 'Grade A', which allows for 0-4 defective pixels. A defective pixel could be solid Black (Dead), White, Red, Green or Blue.

Revision History

Datasheet Revision

Revision Number Date Description
1.0 04/11/2024 Initial Public Release Version

Hardware Revision

Revision Number Date Description
1.0 08/08/2024 Initial Public Release Version