The flexcan_interrupt example shows how to use FlexCAN driver in none-blocking interrupt way:In this example, 2 boards are connected through CAN bus. Endpoint A(board A) send a CAN Message toEndpoint B(board B) when user press space key in terminal. Endpoint B receive the message, printthe message content to terminal and echo back the message. Endpoint A will increase the receivedmessage and waiting for the next transmission of the user initiated.

The flexcan_loopback_functional example shows how to use the loopback test mode to debug your CAN Bus design:To demonstrates this example, only one board is needed. The example will config one FlexCAN MessageBuffer to Rx Message Buffer and the other FlexCAN Message Buffer to Tx Message Buffer with same ID.After that, the example will send a CAN Message from the Tx Message Buffer to the Rx Message Bufferthrouth internal loopback interconnect and print out the Message payload to terminal.

The flexcan_loopback_edma example shows how to use the EDMA version transactional driver to receiveCAN Message from Rx FIFO:To demonstrates this example, only one board is needed. The example will config one FlexCAN MessageBuffer to Tx Message Buffer and also setup Rx FIFO. After that, the example will send 4 CAN Messagesfrom Tx Message Buffer to Rx FIFO through internal loopback interconnect and read them out usingEDMA version FlexCAN transactional driver. The Sent and received message will be print out to terminalat last.

The flexcan_loopback example shows how to use the loopback test mode to debug your CAN Bus design:To demonstrates this example, only one board is needed. The example will config one FlexCAN MessageBuffer to Rx Message Buffer and the other FlexCAN Message Buffer to Tx Message Buffer with same ID.After that, the example will send a CAN Message from the Tx Message Buffer to the Rx Message Bufferthrough internal loopback interconnect and print out the Message payload to terminal.

The FTM project is a demonstration program of generating a combined PWM signal by the SDK FTM driver. It sets up the FTMhardware block to output PWM signals on two TPM channels. The example also shows the complementary mode of operationand deadtime insertion.On boards that have 2 LEDs connected to the FTM pins, the user will see a change in LED brightness.And if the board do not support LEDs to show, the outputs can be observed by oscilloscope.

The FTM project is a demonstration program of the SDK FTM driver's dual-edge capture feature.This feature is available only on certain SoC's.The example sets up a FTM channel-pair for dual-edge capture. Once the input signal is received,this example will print the capture values and period of the input signal on the terminal window.

The FTM project is a demonstration program of the SDK FTM driver's input capture feature.The example sets up a FTM channel for dual-edge capture. Once the input signal is received,this example will print the capture value.

The FTM project is a demonstration program of the SDK FTM driver's output compare feature.It sets up one FTM channel to toggle the output when a match occurs with the channel value. The usershould probe the FTM output with a oscilloscope to see the signal toggling.

The FTM / PDB demo application demonstrates how to use the FTM external trigger to start the ADC conversion using thePDB. FTM0 is configured as a complementary combined mode, and each channel output frequency is 16 KHz. The complementarychannel dead time is 1 µs. The PDB pre-trigger works in back-to-back mode. The ADC0 and ADC1 work in single-end mode.The ADC0 uses channel 1 and channel 5, and ADC1 uses channel 1 and channel 7.

The FTM pwm two channel Example project is a demonstration program that uses the KSDK software to generate a square pulse PWM on 2 channel to control the LED brightness.- FTM generates a PWM with the increasing and decreasing duty cycle.- LED brightness is increasing and then dimming. This is a continuous process.