Communication Peripherals

Configure and use communication peripherals such as CAN, I2C, IPC, SCI, SPI, TCP, UDP, and more

Create Simulink^® models with the communication peripherals such as CAN, I2C, IPC, SCI, SPI, and more available on TI’s C2000™ microcontrollers. Configure the Simulink model to interface with supported target hardware using model configuration parameters. You can map tasks and peripherals in a model to hardware board configurations using Hardware Mapping tool.

Blocks

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C28x

C28x CAN Receive	Enhanced Controller Area Network receive mailbox
C28x CAN Transmit	Enhanced Controller Area Network transmit mailbox
MCAN Receive	Read data from CAN bus (Since R2021a)
MCAN Transmit	Send serial data to CAN bus (Since R2021a)
MCAN Interrupt Status	Output specific bits of MCAN interrupt register or entire register (Since R2021b)
C28x I2C Receive	Configure inter-integrated circuit (I2C) module to receive data from I2C bus
C28x I2C Transmit	Configure inter-integrated circuit (I2C) module to transmit data to I2C bus
Interprocess Data Read	Receive messages from another processor using interprocess communication channel (Since R2020b)
Interprocess Data Write	Send messages to another processor using interprocessor data write (Since R2020b)
Interprocess Data Channel	Model interprocessor data channel between two processors (Since R2020b)
C28x SCI Receive	Receive data on target via serial communication interface (SCI) from host
C28x SCI Transmit	Transmit data from target via serial communication interface (SCI) to host
C28x SPI Controller Transfer	Write data to and read data from SPI peripheral device
C28x SPI Receive	Receive data through Serial Peripheral Interface (SPI) on target
C28x SPI Transmit	Transmit data through Serial Peripheral Interface (SPI) on target
C2803x LIN Receive	Receive data via local interconnect network (LIN) module on target
C2803x LIN Transmit	Transmit data from target via serial communications interface (SCI) to host
C29x UART Receive	Receive data from the Universal Asynchronous Receiver Transmitter (UART) port (Since R2025a)
C29x UART Transmit	Send serial data to the Universal Asynchronous Receiver Transmitter (UART) port (Since R2025a)

Arm Cortex - M3/M4

MCAN Receive	Read data from CAN bus (Since R2021a)
MCAN Transmit	Send serial data to CAN bus (Since R2021a)
MCAN Interrupt Status	Output specific bits of MCAN interrupt register or entire register (Since R2021b)
F2838x-M4 TCP Receive	Receive data over TCP/IP network from remote host (Since R2020b)
F2838x-M4 TCP Send	Send data over TCP/IP network to remote host (Since R2020b)
F28M35x/F28M36x TCP Send	Send TCP packets to a TCP host on TCP/IP network
F28M35x/F28M36x TCP Receive	Receive TCP packets from TCP host on TCP/IP network
F2838x-M4 UDP Send	Send UDP packets to UDP host (Since R2020b)
F2838x-M4 UDP Receive	Receive UDP packets from UDP host (Since R2020b)
F28M35x/F28M36x UDP Send	Send UDP packets to UDP host
F28M35x/F28M36x UDP Receive	Receive UDP packets from the specified UDP host
F2838x-M4 UART Receive	Receive data from the Universal Asynchronous Receiver Transmitter (UART) port
F2838x-M4 UART Transmit	Send serial data to the Universal Asynchronous Receiver Transmitter (UART) port
F28M35x/F28M36x UART Transmit	Transmit serial data to the Universal Asynchronous Receiver Transmitter (UART) port
F28M35x/F28M36x UART Receive	Receive data from the Universal Asynchronous Receiver Transmitter (UART) port
F2838x-M4 Hardware Interrupt	Trigger downstream function-call subsystem from interrupt service routine (Since R2020b)
F28M3xx-M3 Hardware Interrupt	Trigger downstream function-call subsystem from interrupt service routine

F2837x/F2838x IPC (Flat Model Semantics)

F2837xD/F2838x/F2838x-M4 IPC Receive	Receive data from either core while using separate model for each core
F2837xD/F2838x/F2838x-M4 IPC Transmit	Transmit data to either core while using separate model for each core

Tools

Hardware Mapping

Map tasks and peripherals in a model to hardware board configurations (Since R2022b)

Model Settings

Model Configuration Parameters for Texas Instruments C2000 Processors

Model Configuration Parameters for Texas Instruments F2838x (ARM Cortex-M4)

Model Configuration Parameters for Texas Instruments Concerto F28M3x (ARM Cortex-M3)

Model Configuration Parameters: Code Generation Optimization

Topics

Configuring LIN Communications
The LIN communications architecture supports a single controller node and up to 16 peripheral nodes on a LIN network.
Configuring Timing Parameters for CAN Blocks
Lists the specific blocks whose timing parameters are set with the described process
Communication Between Cores Using IPC Blocks
Use the IPC blocks to communicate between cores in F2837xD and F2838x processors on the TI C2000 processor.
Enhance Code Execution Speed in TI C2000 Simulink Applications
Optimize code for efficient execution.
Implement Signal Routing Using C2000 Crossbar (X-BAR)
Overview of crossbar (X-BAR) in C2000™ blockset.
Exploring TI C2000 Toolchain Options
Utilize TI C2000 toolchains like COFF ABI, EABI, and ARM^® to generate code.
Buffer Logic for Data Transmission
Configure SCI buffers for host-target communication.

Troubleshooting

External Interrupt Workflow for Texas Instruments C2000 Processors

This topic helps you with the workflow for external interrupts.

Troubleshooting External Mode Issues

Troubleshoot the problems when you try to execute TI C2000 Simulink model in External Mode.

Optimizing Baud Rate Settings for External Mode Communication

Optimize baud rates of SCI-A, on-board FTDI, and windows COM port for external mode communication.

Featured Examples

Inter-Processor Communication Using IPC Blocks

Use the IPC blocks to communicate between multiple cores of multi-core of Texas Instruments™ C2000™ Microcontroller Blockset using Simulink® models.

Open Model

Communication Using CAN Blocks

Use the CAN blocks to set up CAN communication between the target hardware and your host computer for Texas Instruments™ C2000™ Microcontroller Blockset.

Open Model

Communication with MCAN Blocks

Use the MCAN blocks to set up MCAN communication between the target hardware and your host computer for Texas Instruments® C2000™ Microcontroller Blockset.

Open Model

Serial Communication Using SCI Blocks

Use the SCI blocks to set up serial communication between the target hardware and your host computer for C2000™ Microcontroller Blockset.

Open Model

LIN-Based Control of PWM Duty Cycle

Use the C28035 LIN Receive, LIN Transmit, and PWM blocks to generate a pulse waveform.

Open Model

Using the I2C Bus to Access Sensors

Use the I2C blocks to communicate with I2C based devices.

Open Model

Using SPI to Read and Write Data to SPI EEPROM

Configure and use SPI blocks to read and write data.

Open Model

Interface LCD Booster Pack with Texas Instruments C2000 Processors

Configure and use the Kentec QVGA Display Booster Pack to display an image using C28x™ peripherals for Texas Instruments™ C2000™ processors.

Open Model

Read Position of BiSS-C Absolute Encoder

Read a position of an absolute encoder using the bidirectional serial/synchronous-continuous (BiSS-C) open protocol in the unidirectional mode. This example implements the BiSS-C protocol using TI C2000 peripherals such as CLB, SPI, ePWM, X-BAR, and GPIO using the C2000™ Microcontroller Blockset.

Open Model

Implement Crossbar (X-BARs) Functionality with C2000 Microcontroller Blockset

Use the Input, Output and ePWM X-BARs available on some of the TI® processors using C2000™ Microcontroller Blockset.

Open Model