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Component: Potentiometer (Analog Input): Difference between revisions

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{{Fcfile|Potentiometer Example.fcfx|Potentiometer Example}}
{{Fcfile|Potentiometer Example.fcfx|Potentiometer Example}}


===Filtering ADC Inputs===


Simple example which uses a filtering technique to provide a digital low pass filter on the ADC readings. The output of the filter is 50% the ADC reading and 50% the previous reading.


{{Fcfile|LPFilter_2D.fcfx|LPFilter}}


In this example the output of the filter is 25% the ADC reading and 75% the previous reading.


{{Fcfile|LPFilter2_2D.fcfx|LPFilter2}}




===Analogue Inputs Window===


 
The [[Analog_Window|Analogue inputs window]] available from the View menu allows you to see the values for all of the analogue inputs which are active in your program. They can also be manually altered by dragging the mouse along one of the sliders.
 
 
 


==Macro reference==
==Macro reference==

Revision as of 07:50, 7 October 2024

Author Matrix TSL
Version 1.0
Category Analog Input


Potentiometer component

Component Source Code

Please click here to download the component source project: FC_Comp_Source_Potentiometer.fcfx

Please click here to view the component source code (Beta): FC_Comp_Source_Potentiometer.fcfx

Detailed description

No detailed description exists yet for this component

Examples

A simple example that shows how to use some common functions of the potentiometer in conjunction with an LCD.

Potentiometer Example

Filtering ADC Inputs

Simple example which uses a filtering technique to provide a digital low pass filter on the ADC readings. The output of the filter is 50% the ADC reading and 50% the previous reading.

LPFilter

In this example the output of the filter is 25% the ADC reading and 75% the previous reading.

LPFilter2


Analogue Inputs Window

The Analogue inputs window available from the View menu allows you to see the values for all of the analogue inputs which are active in your program. They can also be manually altered by dragging the mouse along one of the sliders.

Macro reference

GetAverageByte

GetAverageByte
Read the ADC as a byte 
- BYTE NumSamples
 
- BYTE DelayUs
 
- BYTE Return


GetAverageInt

GetAverageInt
Read the ADC at full bit depth 
- BYTE NumSamples
 
- BYTE DelayUs
 
- UINT Return


GetByte

GetByte
Read the ADC as a byte 
- BYTE Return


GetInt

GetInt
Read the ADC at full bit depth 
- UINT Return


GetString

GetString
Reads the ADC as a direct voltage 
- STRING Return


GetVoltage

GetVoltage
Reads the ADC as a direct voltage 
- FLOAT Return


Property reference

Properties
Connections
Channel
Analogue Input Channel - Which pin is the analogue input connected to? 
Settings
VRef voltage
Used by the GetVoltage or GetString component macros to take an ADC reading and convert it into a Voltage. +VRef voltage x 10mV Default 500 = 5.0V  
VRef option
Defines what is used as the ADC maximum reference. ADC Range = GND to VRef Voltage VDD - Defines the microcontrollers power supply pin as the max reference, VREF+ Pin - Dedicated pin on the microcontroller to allow for a variable reference voltage. 
Conversion speed
Clock setting to select how fast the ADC peripheral will perform an ADC conversion. The FRC setting is based on a RC time base and so will vary with temperature and pressure. Other settings are generally based on divisions of the master clock. 
Acquisition cycles
Number of micro seconds to wait for the ADC input to charge before starting the analogue sample. 
Bit Depth
Maximum number of digital bits the ADC can sample. 8 bit = ADC range 0 - 255 10 bit = ADC range 0 - 1023 12 bit = ADC range 0 - 4095 
Retain Value
 
Appearance
Component Label
 
LabelColour
 
Show Connection Label
 
Show Pin Value
 
Colour Style
 
Fill
 
Frame Outline
 
Frame Fill
 
Pointer Outline
 
Pointer Fill
 
Text
 
Tick Mark Outline
 
Tick Mark Fill
 
Cap Outline
 
Cap Fill
 
Main Image
 
Cap Image
 
Style
 
Type
 
Simulation
Scope Traces
Selects if the scope traces are automatically generated or not