mirror of
https://codeberg.org/mclemens/ubitxv6.git
synced 2024-11-17 19:56:00 -05:00
511 lines
14 KiB
C++
511 lines
14 KiB
C++
/**
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* This source file is under General Public License version 3.
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*
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* This verision uses a built-in Si5351 library
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* Most source code are meant to be understood by the compilers and the computers.
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* Code that has to be hackable needs to be well understood and properly documented.
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* Donald Knuth coined the term Literate Programming to indicate code that is written be
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* easily read and understood.
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*
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* The Raduino is a small board that includes the Arduin Nano, a TFT display and
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* an Si5351a frequency synthesizer. This board is manufactured by HF Signals Electronics Pvt Ltd
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*
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* To learn more about Arduino you may visit www.arduino.cc.
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*
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* The Arduino works by starts executing the code in a function called setup() and then it
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* repeatedly keeps calling loop() forever. All the initialization code is kept in setup()
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* and code to continuously sense the tuning knob, the function button, transmit/receive,
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* etc is all in the loop() function. If you wish to study the code top down, then scroll
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* to the bottom of this file and read your way up.
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*
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* Below are the libraries to be included for building the Raduino
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* The EEPROM library is used to store settings like the frequency memory, caliberation data, etc.
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*
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* The main chip which generates upto three oscillators of various frequencies in the
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* Raduino is the Si5351a. To learn more about Si5351a you can download the datasheet
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* from www.silabs.com although, strictly speaking it is not a requirment to understand this code.
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* Instead, you can look up the Si5351 library written by xxx, yyy. You can download and
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* install it from www.url.com to complile this file.
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* The Wire.h library is used to talk to the Si5351 and we also declare an instance of
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* Si5351 object to control the clocks.
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*/
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#include <Wire.h>
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#include "button_timing.h"
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#include "menu.h"
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#include "menu_main.h"
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#include "morse.h"
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#include "nano_gui.h"
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#include "settings.h"
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#include "setup.h"
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#include "touch.h"
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#include "ui_touch.h"
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#include "ubitx.h"
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/**
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* The Arduino, unlike C/C++ on a regular computer with gigabytes of RAM, has very little memory.
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* We have to be very careful with variables that are declared inside the functions as they are
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* created in a memory region called the stack. The stack has just a few bytes of space on the Arduino
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* if you declare large strings inside functions, they can easily exceed the capacity of the stack
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* and mess up your programs.
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* We circumvent this by declaring a few global buffers as kitchen counters where we can
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* slice and dice our strings. These strings are mostly used to control the display or handle
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* the input and output from the USB port. We must keep a count of the bytes used while reading
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* the serial port as we can easily run out of buffer space. This is done in the serial_in_count variable.
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*/
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char b[128];
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char c[30];
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//during CAT commands, we will freeeze the display until CAT is disengaged
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unsigned char doingCAT = 0;
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/**
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* Below are the basic functions that control the uBitx. Understanding the functions before
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* you start hacking around
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*/
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/**
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* Our own delay. During any delay, the raduino should still be processing a few times.
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*/
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void active_delay(int delay_by){
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unsigned long timeStart = millis();
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while (millis() - timeStart <= (unsigned long)delay_by) {
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checkCAT();
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}
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}
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void saveVFOs()
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{
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SaveSettingsToEeprom();
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}
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/**
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* Select the properly tx harmonic filters
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* The four harmonic filters use only three relays
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* the four LPFs cover 30-21 Mhz, 18 - 14 Mhz, 7-10 MHz and 3.5 to 5 Mhz
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* Briefly, it works like this,
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* - When KT1 is OFF, the 'off' position routes the PA output through the 30 MHz LPF
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* - When KT1 is ON, it routes the PA output to KT2. Which is why you will see that
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* the KT1 is on for the three other cases.
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* - When the KT1 is ON and KT2 is off, the off position of KT2 routes the PA output
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* to 18 MHz LPF (That also works for 14 Mhz)
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* - When KT1 is On, KT2 is On, it routes the PA output to KT3
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* - KT3, when switched on selects the 7-10 Mhz filter
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* - KT3 when switched off selects the 3.5-5 Mhz filter
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* See the circuit to understand this
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*/
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void setTXFilters(unsigned long freq){
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if (freq > 21000000L){ // the default filter is with 35 MHz cut-off
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digitalWrite(TX_LPF_A, 0);
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digitalWrite(TX_LPF_B, 0);
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digitalWrite(TX_LPF_C, 0);
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}
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else if (freq >= 14000000L){ //thrown the KT1 relay on, the 30 MHz LPF is bypassed and the 14-18 MHz LPF is allowd to go through
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digitalWrite(TX_LPF_A, 1);
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digitalWrite(TX_LPF_B, 0);
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digitalWrite(TX_LPF_C, 0);
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}
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else if (freq > 7000000L){
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digitalWrite(TX_LPF_A, 0);
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digitalWrite(TX_LPF_B, 1);
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digitalWrite(TX_LPF_C, 0);
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}
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else {
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digitalWrite(TX_LPF_A, 0);
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digitalWrite(TX_LPF_B, 0);
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digitalWrite(TX_LPF_C, 1);
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}
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}
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void setTXFilters_v5(unsigned long freq){
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if (freq > 21000000L){ // the default filter is with 35 MHz cut-off
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digitalWrite(TX_LPF_A, 0);
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digitalWrite(TX_LPF_B, 0);
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digitalWrite(TX_LPF_C, 0);
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}
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else if (freq >= 14000000L){ //thrown the KT1 relay on, the 30 MHz LPF is bypassed and the 14-18 MHz LPF is allowd to go through
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digitalWrite(TX_LPF_A, 1);
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digitalWrite(TX_LPF_B, 0);
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digitalWrite(TX_LPF_C, 0);
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}
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else if (freq > 7000000L){
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digitalWrite(TX_LPF_A, 0);
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digitalWrite(TX_LPF_B, 1);
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digitalWrite(TX_LPF_C, 0);
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}
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else {
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digitalWrite(TX_LPF_A, 0);
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digitalWrite(TX_LPF_B, 0);
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digitalWrite(TX_LPF_C, 1);
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}
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}
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/**
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* This is the most frequently called function that configures the
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* radio to a particular frequeny, sideband and sets up the transmit filters
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*
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* The transmit filter relays are powered up only during the tx so they dont
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* draw any current during rx.
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*
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* The carrier oscillator of the detector/modulator is permanently fixed at
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* uppper sideband. The sideband selection is done by placing the second oscillator
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* either 12 Mhz below or above the 45 Mhz signal thereby inverting the sidebands
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* through mixing of the second local oscillator.
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*/
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void setFrequency(const unsigned long freq,
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const bool transmit){
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static const unsigned long FIRST_IF = 45005000UL;
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setTXFilters(freq);
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//Nominal values for the oscillators
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uint32_t local_osc_freq = FIRST_IF + freq;
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uint32_t ssb_osc_freq = FIRST_IF;//will be changed depending on sideband
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uint32_t bfo_osc_freq = globalSettings.usbCarrierFreq;
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if(TuningMode_e::TUNE_CW == globalSettings.tuningMode){
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if(transmit){
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//We don't do any mixing or converting when transmitting
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local_osc_freq = freq;
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ssb_osc_freq = 0;
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bfo_osc_freq = 0;
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}
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else{
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//We offset when receiving CW so that it's audible
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if(VfoMode_e::VFO_MODE_USB == GetActiveVfoMode()){
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local_osc_freq -= globalSettings.cwSideToneFreq;
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ssb_osc_freq += globalSettings.usbCarrierFreq;
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}
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else{
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local_osc_freq += globalSettings.cwSideToneFreq;
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ssb_osc_freq -= globalSettings.usbCarrierFreq;
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}
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}
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}
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else{//SSB mode
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if(VfoMode_e::VFO_MODE_USB == GetActiveVfoMode()){
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ssb_osc_freq += globalSettings.usbCarrierFreq;
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}
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else{
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ssb_osc_freq -= globalSettings.usbCarrierFreq;
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}
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}
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si5351bx_setfreq(2, local_osc_freq);
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si5351bx_setfreq(1, ssb_osc_freq);
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si5351bx_setfreq(0, bfo_osc_freq);
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SetActiveVfoFreq(freq);
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}
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/**
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* startTx is called by the PTT, cw keyer and CAT protocol to
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* put the uBitx in tx mode. It takes care of rit settings, sideband settings
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* Note: In cw mode, doesnt key the radio, only puts it in tx mode
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* CW offest is calculated as lower than the operating frequency when in LSB mode, and vice versa in USB mode
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*/
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void startTx(TuningMode_e tx_mode){
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globalSettings.tuningMode = tx_mode;
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if (globalSettings.ritOn){
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//save the current as the rx frequency
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uint32_t rit_tx_freq = globalSettings.ritFrequency;
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globalSettings.ritFrequency = GetActiveVfoFreq();
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setFrequency(rit_tx_freq,true);
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}
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else{
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if(globalSettings.splitOn){
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if(Vfo_e::VFO_B == globalSettings.activeVfo){
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globalSettings.activeVfo = Vfo_e::VFO_A;
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}
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else{
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globalSettings.activeVfo = Vfo_e::VFO_B;
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}
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}
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setFrequency(GetActiveVfoFreq(),true);
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}
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digitalWrite(TX_RX, 1);//turn on the tx
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globalSettings.txActive = true;
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drawTx();
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}
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void stopTx(){
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digitalWrite(TX_RX, 0);//turn off the tx
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globalSettings.txActive = false;
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if(globalSettings.ritOn){
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uint32_t rit_rx_freq = globalSettings.ritFrequency;
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globalSettings.ritFrequency = GetActiveVfoFreq();
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setFrequency(rit_rx_freq);
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}
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else{
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if(globalSettings.splitOn){
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if(Vfo_e::VFO_B == globalSettings.activeVfo){
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globalSettings.activeVfo = Vfo_e::VFO_A;
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}
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else{
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globalSettings.activeVfo = Vfo_e::VFO_B;
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}
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}
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setFrequency(GetActiveVfoFreq());
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}
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drawTx();
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}
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/**
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* ritEnable is called with a frequency parameter that determines
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* what the tx frequency will be
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*/
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void ritEnable(unsigned long freq){
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globalSettings.ritOn = true;
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//save the non-rit frequency back into the VFO memory
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//as RIT is a temporary shift, this is not saved to EEPROM
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globalSettings.ritFrequency = freq;
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}
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// this is called by the RIT menu routine
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void ritDisable(){
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if(globalSettings.ritOn){
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globalSettings.ritOn = false;
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setFrequency(globalSettings.ritFrequency);
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updateDisplay();
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}
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}
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/**
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* Basic User Interface Routines. These check the front panel for any activity
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*/
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/**
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* The PTT is checked only if we are not already in a cw transmit session
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* If the PTT is pressed, we shift to the ritbase if the rit was on
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* flip the T/R line to T and update the display to denote transmission
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*/
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void checkPTT(){
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//we don't check for ptt when transmitting cw
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if (globalSettings.cwExpirationTimeMs > 0){
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return;
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}
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if(digitalRead(PTT) == 0 && !globalSettings.txActive){
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startTx(TuningMode_e::TUNE_SSB);
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active_delay(50); //debounce the PTT
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}
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if (digitalRead(PTT) == 1 && globalSettings.txActive)
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stopTx();
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}
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//check if the encoder button was pressed
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ButtonPress_e checkButton(){
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if (!btnDown()){
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return ButtonPress_e::NotPressed;
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}
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delay(DEBOUNCE_DELAY_MS);
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if (!btnDown()){//debounce
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return ButtonPress_e::NotPressed;
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}
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uint16_t down_time = 0;
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while(btnDown() && (down_time < LONG_PRESS_TIME_MS)){
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delay(LONG_PRESS_POLL_TIME_MS);
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down_time += LONG_PRESS_POLL_TIME_MS;
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}
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if(down_time < LONG_PRESS_TIME_MS){
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return ButtonPress_e::ShortPress;
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}
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else{
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return ButtonPress_e::LongPress;
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}
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}
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void switchVFO(Vfo_e new_vfo){
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ritDisable();//If we are in RIT mode, we need to disable it before setting the active VFO so that the correct VFO gets it's frequency restored
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globalSettings.activeVfo = new_vfo;
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setFrequency(GetActiveVfoFreq());
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redrawVFOs();
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saveVFOs();
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}
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/**
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* The tuning jumps by 50 Hz on each step when you tune slowly
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* As you spin the encoder faster, the jump size also increases
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* This way, you can quickly move to another band by just spinning the
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* tuning knob
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*/
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void doTuning(){
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static unsigned long prev_freq;
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static unsigned long nextFrequencyUpdate = 0;
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unsigned long now = millis();
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if (now >= nextFrequencyUpdate && prev_freq != GetActiveVfoFreq()){
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updateDisplay();
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nextFrequencyUpdate = now + 100;
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prev_freq = GetActiveVfoFreq();
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}
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int s = enc_read();
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if (!s)
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return;
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//Serial.println(s);
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doingCAT = 0; // go back to manual mode if you were doing CAT
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prev_freq = GetActiveVfoFreq();
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uint32_t new_freq = prev_freq;
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if (s > 10 || s < -10){
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new_freq += 200L * s;
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}
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else if (s > 5 || s < -5){
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new_freq += 100L * s;
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}
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else{
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new_freq += 50L * s;
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}
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//Transition from below to above the traditional threshold for USB
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if(prev_freq < THRESHOLD_USB_LSB && new_freq >= THRESHOLD_USB_LSB){
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SetActiveVfoMode(VfoMode_e::VFO_MODE_USB);
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}
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//Transition from aboveo to below the traditional threshold for USB
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if(prev_freq >= THRESHOLD_USB_LSB && new_freq < THRESHOLD_USB_LSB){
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SetActiveVfoMode(VfoMode_e::VFO_MODE_LSB);
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}
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setFrequency(new_freq);
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}
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/**
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* RIT only steps back and forth by 100 hz at a time
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*/
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void doRIT(){
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int knob = enc_read();
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uint32_t old_freq = GetActiveVfoFreq();
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uint32_t new_freq = old_freq;
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if (knob < 0)
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new_freq -= 100l;
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else if (knob > 0)
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new_freq += 100;
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if (old_freq != new_freq){
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setFrequency(new_freq);
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updateDisplay();
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}
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}
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/**
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* The settings are read from EEPROM. The first time around, the values may not be
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* present or out of range, in this case, some intelligent defaults are copied into the
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* variables.
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*/
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void initSettings(){
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LoadDefaultSettings();
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LoadSettingsFromEeprom();
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}
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void initPorts(){
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analogReference(DEFAULT);
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//??
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pinMode(ENC_A, INPUT_PULLUP);
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pinMode(ENC_B, INPUT_PULLUP);
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pinMode(FBUTTON, INPUT_PULLUP);
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enc_setup();
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//configure the function button to use the external pull-up
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// pinMode(FBUTTON, INPUT);
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// digitalWrite(FBUTTON, HIGH);
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pinMode(PTT, INPUT_PULLUP);
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// pinMode(ANALOG_KEYER, INPUT_PULLUP);
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pinMode(CW_TONE, OUTPUT);
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digitalWrite(CW_TONE, 0);
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pinMode(TX_RX,OUTPUT);
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digitalWrite(TX_RX, 0);
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pinMode(TX_LPF_A, OUTPUT);
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pinMode(TX_LPF_B, OUTPUT);
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pinMode(TX_LPF_C, OUTPUT);
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digitalWrite(TX_LPF_A, 0);
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digitalWrite(TX_LPF_B, 0);
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digitalWrite(TX_LPF_C, 0);
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pinMode(CW_KEY, OUTPUT);
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digitalWrite(CW_KEY, 0);
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}
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void setup()
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{
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Serial.begin(38400);
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Serial.flush();
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initSettings();
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displayInit();
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initTouch();
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initPorts();
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initOscillators();
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setFrequency(globalSettings.vfoA.frequency);
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//Run initial calibration routine if button is pressed during power up
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if(btnDown()){
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LoadDefaultSettings();
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setupTouch();
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SetActiveVfoMode(VfoMode_e::VFO_MODE_USB);
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setFrequency(10000000L);
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runLocalOscSetting();
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SetActiveVfoMode(VfoMode_e::VFO_MODE_LSB);
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setFrequency(7100000L);
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runBfoSetting();
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}
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rootMenu->initMenu();
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}
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/**
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* The loop checks for keydown, ptt, function button and tuning.
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*/
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void loop(){
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if(TuningMode_e::TUNE_CW == globalSettings.tuningMode){
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cwKeyer();
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}
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else if(!globalSettings.txCatActive){
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checkPTT();
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}
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checkCAT();
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if(globalSettings.txActive){
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//Don't run menus when transmitting
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return;
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}
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ButtonPress_e tuner_button = checkButton();
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Point touch_point;
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ButtonPress_e touch_button = checkTouch(&touch_point);
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int16_t knob = enc_read();
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rootMenu->runMenu(tuner_button,touch_button,touch_point,knob);
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}
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