Basic example header for demo_esp project. More...

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Functions
int	basic_example_main ()
	basic example main execution. More...

Detailed Description

Basic example header for demo_esp project.

Author: Antoniu Miclaus (anton.nosp@m.iu.m.nosp@m.iclau.nosp@m.s@an.nosp@m.alog..nosp@m.com)

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Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.
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Function Documentation

◆ basic_example_main()

int basic_example_main ( )

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute print the sample data.; ret - 0 on success.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously the while(1) loop and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously function basic_app_run and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will measure active and reactive energy and RMS for channel A and for voltage stopping whenever an interrupt occurs and resulting in a stoppage of the measurement.; ret - Result of the example execution. If working correctly, will execute print the sample data.; ret - 0 on success.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously the while(1) loop and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously function basic_app_run and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will measure active and reactive energy and RMS for channel A and for voltage stopping whenever an interrupt occurs and resulting in a stoppage of the measurement.

basic example main execution.

Returns: ret - Result of the example execution.; ret - Result of the example execution. If working correctly, will execute print the sample data.; ret - 0 on success.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously the while(1) loop and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously function basic_app_run and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will measure active and reactive energy and RMS for channel A and for voltage stopping whenever an interrupt occurs and resulting in a stoppage of the measurement.

basic example main execution.

Returns: ret - Result of the example execution.; ret - Result of the example execution.; ret - Result of the example execution. If working correctly, will execute print the sample data.; ret - 0 on success.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously the while(1) loop and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously function basic_app_run and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will measure active and reactive energy and RMS for channel A and for voltage stopping whenever an interrupt occurs and resulting in a stoppage of the measurement.

basic example main execution.

Returns: ret - Result of the example execution.; ret - Result of the example execution.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will turn the status led's on and off in the while loop, set some values in the config 2 register, and then return 0.; ret - Result of the example execution. If working correctly, will execute print the sample data.; ret - 0 on success.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously the while(1) loop and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously function basic_app_run and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will measure active and reactive energy and RMS for channel A and for voltage stopping whenever an interrupt occurs and resulting in a stoppage of the measurement.

basic example main execution.

Returns: ret - Result of the example execution.; ret - Result of the example execution.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will turn the status led's on and off in the while loop, set some values in the config 2 register, and then return 0.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will show the user for each channels if there is digital input present or not. It also changes delay values for channel 3 and sets the state for channel 0 to OFF. If all these operations were performed correctly 0 will be returned.

basic example main execution.

Returns: ret - Result for the main execution of the example. If working correctly the device's channel 0 will be set to SOURCE mode and also have delay values changed. Counter values for channel 0 will be changed as well and printed afterwards. 0 will be returned at the end in case of succes.; ret - Result of the example execution. If working correctly, will execute print the sample data.; ret - 0 on success.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously the while(1) loop and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will execute continuously function basic_app_run and will not return.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will measure active and reactive energy and RMS for channel A and for voltage stopping whenever an interrupt occurs and resulting in a stoppage of the measurement.

basic example main execution.

Returns: ret - Result of the example execution.; ret - Result of the example execution.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will turn the status led's on and off in the while loop, set some values in the config 2 register, and then return 0.

basic example main execution.

Returns: ret - Result of the example execution. If working correctly, will show the user for each channels if there is digital input present or not. It also changes delay values for channel 3 and sets the state for channel 0 to OFF. If all these operations were performed correctly 0 will be returned.

basic example main execution.

Returns: ret - Result for the main execution of the example. If working correctly the device's channel 0 will be set to SOURCE mode and also have delay values changed. Counter values for channel 0 will be changed as well and printed afterwards. 0 will be returned at the end in case of succes.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

GPIO Pin Interrupt Controller

Parameter to be passed when the callback is called.

GPIO Pin Interrupt Controller

MAX14906 Initialization

Setting SLED set bit 1 in the config register.

Turning the Status LEDs on, then off.

Setting a current limit for channel 0.

Read current limit for all channels.

Setting the on state for channel 0, and then verifying it.

Maximum value of 3V.

The increment of the AO1 to be used (needs to be smaller then the SR step-size).

Frequency of the signal.

Initializing GPIO 0 of MAX22017.

Setting its value to HIGH.

Changing operation mode of MAX22017.

Changing configuration of MAX22017.

Changing slew-rate configuration of MAX22017.

Reading the GAIN correction.

Functions

Detailed Description

Function Documentation

◆ basic_example_main()