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/**
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Since KD8CEC Version 0.29 , most of the original code is no longer available .
Most features ( TX , Frequency Range , Ham Band , TX Control , CW delay , start Delay . . . more ) have been added by KD8CEC .
However , the license rules are subject to the original source rules .
DE Ian KD8CEC
Original source comment - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
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* This source file is under General Public License version 3.
*
* This verision uses a built - in Si5351 library
* Most source code are meant to be understood by the compilers and the computers .
* Code that has to be hackable needs to be well understood and properly documented .
* Donald Knuth coined the term Literate Programming to indicate code that is written be
* easily read and understood .
*
* The Raduino is a small board that includes the Arduin Nano , a 16 x2 LCD display and
* an Si5351a frequency synthesizer . This board is manufactured by Paradigm Ecomm Pvt Ltd
*
* To learn more about Arduino you may visit www . arduino . cc .
*
* The Arduino works by starts executing the code in a function called setup ( ) and then it
* repeatedly keeps calling loop ( ) forever . All the initialization code is kept in setup ( )
* and code to continuously sense the tuning knob , the function button , transmit / receive ,
* etc is all in the loop ( ) function . If you wish to study the code top down , then scroll
* to the bottom of this file and read your way up .
*
* Below are the libraries to be included for building the Raduino
* The EEPROM library is used to store settings like the frequency memory , caliberation data ,
* callsign etc .
*
* The main chip which generates upto three oscillators of various frequencies in the
* Raduino is the Si5351a . To learn more about Si5351a you can download the datasheet
* from www . silabs . com although , strictly speaking it is not a requirment to understand this code .
* Instead , you can look up the Si5351 library written by xxx , yyy . You can download and
* install it from www . url . com to complile this file .
* The Wire . h library is used to talk to the Si5351 and we also declare an instance of
* Si5351 object to control the clocks .
*/
# include <Wire.h>
# include <EEPROM.h>
/**
The main chip which generates upto three oscillators of various frequencies in the
Raduino is the Si5351a . To learn more about Si5351a you can download the datasheet
from www . silabs . com although , strictly speaking it is not a requirment to understand this code .
We no longer use the standard SI5351 library because of its huge overhead due to many unused
features consuming a lot of program space . Instead of depending on an external library we now use
Jerry Gaffke ' s , KE7ER , lightweight standalone mimimalist " si5351bx " routines ( see further down the
code ) . Here are some defines and declarations used by Jerry ' s routines :
*/
/**
* We need to carefully pick assignment of pin for various purposes .
* There are two sets of completely programmable pins on the Raduino .
* First , on the top of the board , in line with the LCD connector is an 8 - pin connector
* that is largely meant for analog inputs and front - panel control . It has a regulated 5 v output ,
* ground and six pins . Each of these six pins can be individually programmed
* either as an analog input , a digital input or a digital output .
* The pins are assigned as follows ( left to right , display facing you ) :
* Pin 1 ( Violet ) , A7 , SPARE
* Pin 2 ( Blue ) , A6 , KEYER ( DATA )
* Pin 3 ( Green ) , + 5 v
* Pin 4 ( Yellow ) , Gnd
* Pin 5 ( Orange ) , A3 , PTT
* Pin 6 ( Red ) , A2 , F BUTTON
* Pin 7 ( Brown ) , A1 , ENC B
* Pin 8 ( Black ) , A0 , ENC A
* Note : A5 , A4 are wired to the Si5351 as I2C interface
* *
* Though , this can be assigned anyway , for this application of the Arduino , we will make the following
* assignment
* A2 will connect to the PTT line , which is the usually a part of the mic connector
* A3 is connected to a push button that can momentarily ground this line . This will be used for RIT / Bandswitching , etc .
* A6 is to implement a keyer , it is reserved and not yet implemented
* A7 is connected to a center pin of good quality 100 K or 10 K linear potentiometer with the two other ends connected to
* ground and + 5 v lines available on the connector . This implments the tuning mechanism
*/
# define ENC_A (A0)
# define ENC_B (A1)
# define FBUTTON (A2)
# define PTT (A3)
# define ANALOG_KEYER (A6)
# define ANALOG_SPARE (A7)
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# define ANALOG_SMETER (A7) //by KD8CEC
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/**
* The Raduino board is the size of a standard 16 x2 LCD panel . It has three connectors :
*
* First , is an 8 pin connector that provides + 5 v , GND and six analog input pins that can also be
* configured to be used as digital input or output pins . These are referred to as A0 , A1 , A2 ,
* A3 , A6 and A7 pins . The A4 and A5 pins are missing from this connector as they are used to
* talk to the Si5351 over I2C protocol .
*
* Second is a 16 pin LCD connector . This connector is meant specifically for the standard 16 x2
* LCD display in 4 bit mode . The 4 bit mode requires 4 data lines and two control lines to work :
* Lines used are : RESET , ENABLE , D4 , D5 , D6 , D7
* We include the library and declare the configuration of the LCD panel too
*/
# include <LiquidCrystal.h>
LiquidCrystal lcd ( 8 , 9 , 10 , 11 , 12 , 13 ) ;
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# define VERSION_NUM 0x01 //for KD8CEC'S firmware and for memory management software
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/**
* The Arduino , unlike C / C + + on a regular computer with gigabytes of RAM , has very little memory .
* We have to be very careful with variables that are declared inside the functions as they are
* created in a memory region called the stack . The stack has just a few bytes of space on the Arduino
* if you declare large strings inside functions , they can easily exceed the capacity of the stack
* and mess up your programs .
* We circumvent this by declaring a few global buffers as kitchen counters where we can
* slice and dice our strings . These strings are mostly used to control the display or handle
* the input and output from the USB port . We must keep a count of the bytes used while reading
* the serial port as we can easily run out of buffer space . This is done in the serial_in_count variable .
*/
char c [ 30 ] , b [ 30 ] ;
char printBuff [ 2 ] [ 17 ] ; //mirrors what is showing on the two lines of the display
int count = 0 ; //to generally count ticks, loops, etc
/**
* The second set of 16 pins on the Raduino ' s bottom connector are have the three clock outputs and the digital lines to control the rig .
* This assignment is as follows :
* Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
* GND + 5 V CLK0 GND GND CLK1 GND GND CLK2 GND D2 D3 D4 D5 D6 D7
* These too are flexible with what you may do with them , for the Raduino , we use them to :
* - TX_RX line : Switches between Transmit and Receive after sensing the PTT or the morse keyer
* - CW_KEY line : turns on the carrier for CW
*/
# define TX_RX (7)
# define CW_TONE (6)
# define TX_LPF_A (5)
# define TX_LPF_B (4)
# define TX_LPF_C (3)
# define CW_KEY (2)
/**
* These are the indices where these user changable settinngs are stored in the EEPROM
*/
# define MASTER_CAL 0
# define LSB_CAL 4
# define USB_CAL 8
# define SIDE_TONE 12
//these are ids of the vfos as well as their offset into the eeprom storage, don't change these 'magic' values
# define VFO_A 16
# define VFO_B 20
# define CW_SIDETONE 24
# define CW_SPEED 28
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//AT328 has 1KBytes EEPROM
# define VFO_A_MODE 256
# define VFO_B_MODE 257
# define CW_DELAY 258
# define CW_START 259
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# define HAM_BAND_COUNT 260 //
# define TX_TUNE_TYPE 261 //
# define HAM_BAND_RANGE 262 //FROM (2BYTE) TO (2BYTE) * 10 = 40byte
# define HAM_BAND_FREQS 302 //40, 1 BAND = 4Byte most bit is mode
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# define TUNING_STEP 342 //TUNING STEP * 6 (index 1 + STEPS 5)
//for reduce cw key error, eeprom address
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# define CW_ADC_MOST_BIT1 348 //most 2bits of DOT_TO , DOT_FROM, ST_TO, ST_FROM
# define CW_ADC_ST_FROM 349 //CW ADC Range STRAIGHT KEY from (Lower 8 bit)
# define CW_ADC_ST_TO 350 //CW ADC Range STRAIGHT KEY to (Lower 8 bit)
# define CW_ADC_DOT_FROM 351 //CW ADC Range DOT from (Lower 8 bit)
# define CW_ADC_DOT_TO 352 //CW ADC Range DOT to (Lower 8 bit)
# define CW_ADC_MOST_BIT2 353 //most 2bits of BOTH_TO, BOTH_FROM, DASH_TO, DASH_FROM
# define CW_ADC_DASH_FROM 354 //CW ADC Range DASH from (Lower 8 bit)
# define CW_ADC_DASH_TO 355 //CW ADC Range DASH to (Lower 8 bit)
# define CW_ADC_BOTH_FROM 356 //CW ADC Range BOTH from (Lower 8 bit)
# define CW_ADC_BOTH_TO 357 //CW ADC Range BOTH to (Lower 8 bit)
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# define CW_KEY_TYPE 358
# define DISPLAY_OPTION1 361 //Display Option1
# define DISPLAY_OPTION2 362 //Display Option2
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//Check Firmware type and version
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# define FIRMWAR_ID_ADDR 776 //776 : 0x59, 777 :0x58, 778 : 0x68 : Id Number, if not found id, erase eeprom(32~1023) for prevent system error.
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# define VERSION_ADDRESS 779 //check Firmware version
//USER INFORMATION
# define USER_CALLSIGN_KEY 780 //0x59
# define USER_CALLSIGN_LEN 781 //1BYTE (OPTION + LENGTH) + CALLSIGN (MAXIMUM 18)
# define USER_CALLSIGN_DAT 782 //CALL SIGN DATA //direct EEPROM to LCD basic offset
//AUTO KEY STRUCTURE
//AUTO KEY USE 800 ~ 1023
# define CW_AUTO_MAGIC_KEY 800 //0x73
# define CW_AUTO_COUNT 801 //0 ~ 255
# define CW_AUTO_DATA 803 //[INDEX, INDEX, INDEX,DATA,DATA, DATA (Positon offset is CW_AUTO_DATA
# define CW_DATA_OFSTADJ CW_AUTO_DATA - USER_CALLSIGN_DAT //offset adjust for ditect eeprom to lcd (basic offset is USER_CALLSIGN_DAT
# define CW_STATION_LEN 1023 //value range : 4 ~ 30
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/**
* The uBITX is an upconnversion transceiver . The first IF is at 45 MHz .
* The first IF frequency is not exactly at 45 Mhz but about 5 khz lower ,
* this shift is due to the loading on the 45 Mhz crystal filter by the matching
* L - network used on it ' s either sides .
* The first oscillator works between 48 Mhz and 75 MHz . The signal is subtracted
* from the first oscillator to arriive at 45 Mhz IF . Thus , it is inverted : LSB becomes USB
* and USB becomes LSB .
* The second IF of 12 Mhz has a ladder crystal filter . If a second oscillator is used at
* 57 Mhz , the signal is subtracted FROM the oscillator , inverting a second time , and arrives
* at the 12 Mhz ladder filter thus doouble inversion , keeps the sidebands as they originally were .
* If the second oscillator is at 33 Mhz , the oscilaltor is subtracated from the signal ,
* thus keeping the signal ' s sidebands inverted . The USB will become LSB .
* We use this technique to switch sidebands . This is to avoid placing the lsbCarrier close to
* 12 MHz where its fifth harmonic beats with the arduino ' s 16 Mhz oscillator ' s fourth harmonic
*/
// the second oscillator should ideally be at 57 MHz, however, the crystal filter's center frequency
// is shifted down a little due to the loading from the impedance matching L-networks on either sides
# define SECOND_OSC_USB (56995000l)
# define SECOND_OSC_LSB (32995000l)
//these are the two default USB and LSB frequencies. The best frequencies depend upon your individual taste and filter shape
# define INIT_USB_FREQ (11996500l)
// limits the tuning and working range of the ubitx between 3 MHz and 30 MHz
# define LOWEST_FREQ (3000000l)
# define HIGHEST_FREQ (30000000l)
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//When the frequency is moved by the dial, the maximum value by KD8CEC
# define LOWEST_FREQ_DIAL (3000l)
# define HIGHEST_FREQ_DIAL (60000000l)
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//we directly generate the CW by programmin the Si5351 to the cw tx frequency, hence, both are different modes
//these are the parameter passed to startTx
# define TX_SSB 0
# define TX_CW 1
char ritOn = 0 ;
char vfoActive = VFO_A ;
int8_t meter_reading = 0 ; // a -1 on meter makes it invisible
unsigned long vfoA = 7150000L , vfoB = 14200000L , sideTone = 800 , usbCarrier ;
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unsigned long vfoA_eeprom , vfoB_eeprom ; //for protect eeprom life
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unsigned long frequency , ritRxFrequency , ritTxFrequency ; //frequency is the current frequency on the dial
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unsigned int cwSpeed = 100 ; //this is actuall the dot period in milliseconds
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extern int32_t calibration ;
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//for store the mode in eeprom
byte vfoA_mode = 0 , vfoB_mode = 0 ; //0: default, 1:not use, 2:LSB, 3:USB, 4:CW, 5:AM, 6:FM
byte vfoA_mode_eeprom , vfoB_mode_eeprom ; //for protect eeprom life
//KD8CEC
//for AutoSave and protect eeprom life
byte saveIntervalSec = 10 ; //second
unsigned long saveCheckTime = 0 ;
unsigned long saveCheckFreq = 0 ;
bool isSplitOn = false ;
byte cwDelayTime = 60 ;
byte delayBeforeCWStartTime = 50 ;
//sideTonePitch + sideToneSub = sideTone
byte sideTonePitch = 0 ;
byte sideToneSub = 0 ;
//DialLock
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byte isDialLock = 0 ; //000000[0]vfoB [0]vfoA 0Bit : A, 1Bit : B
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byte isTxType = 0 ; //000000[0 - isSplit] [0 - isTXStop]
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byte arTuneStep [ 5 ] ;
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byte tuneStepIndex ; //default Value 0, start Offset is 0 because of check new user
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byte displayOption1 = 0 ;
byte displayOption2 = 0 ;
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//CW ADC Range
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int cwAdcSTFrom = 0 ;
int cwAdcSTTo = 0 ;
int cwAdcDotFrom = 0 ;
int cwAdcDotTo = 0 ;
int cwAdcDashFrom = 0 ;
int cwAdcDashTo = 0 ;
int cwAdcBothFrom = 0 ;
int cwAdcBothTo = 0 ;
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byte cwKeyType = 0 ; //0: straight, 1 : iambica, 2: iambicb
bool Iambic_Key = true ;
# define IAMBICB 0x10 // 0 for Iambic A, 1 for Iambic B
unsigned char keyerControl = IAMBICB ;
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//Variables for auto cw mode
byte isCWAutoMode = 0 ; //0 : none, 1 : CW_AutoMode_Menu_Selection, 2 : CW_AutoMode Sending
byte cwAutoTextCount = 0 ; //cwAutoText Count
byte beforeCWTextIndex = 255 ; //when auto cw start, always beforeCWTextIndex = 255, (for first time check)
byte cwAutoDialType = 0 ; //0 : CW Text Change, 1 : Frequency Tune
# define AUTO_CW_RESERVE_MAX 3
byte autoCWSendReserv [ AUTO_CW_RESERVE_MAX ] ; //Reserve CW Auto Send
byte autoCWSendReservCount = 0 ; //Reserve CW Text Cound
byte sendingCWTextIndex = 0 ; //cw auto seding Text Index
byte userCallsignLength = 0 ; //7 : display callsign at system startup, 6~0 : callsign length (range : 1~18)
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/**
* Raduino needs to keep track of current state of the transceiver . These are a few variables that do it
*/
boolean txCAT = false ; //turned on if the transmitting due to a CAT command
char inTx = 0 ; //it is set to 1 if in transmit mode (whatever the reason : cw, ptt or cat)
char splitOn = 0 ; //working split, uses VFO B as the transmit frequency, (NOT IMPLEMENTED YET)
char keyDown = 0 ; //in cw mode, denotes the carrier is being transmitted
char isUSB = 0 ; //upper sideband was selected, this is reset to the default for the
//frequency when it crosses the frequency border of 10 MHz
byte menuOn = 0 ; //set to 1 when the menu is being displayed, if a menu item sets it to zero, the menu is exited
unsigned long cwTimeout = 0 ; //milliseconds to go before the cw transmit line is released and the radio goes back to rx mode
unsigned long dbgCount = 0 ; //not used now
unsigned char txFilter = 0 ; //which of the four transmit filters are in use
boolean modeCalibrate = false ; //this mode of menus shows extended menus to calibrate the oscillators and choose the proper
//beat frequency
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unsigned long beforeIdle_ProcessTime = 0 ; //for check Idle time
byte line2DisplayStatus = 0 ; //0:Clear, 1 : menu, 1: DisplayFrom Idle,
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/**
* Below are the basic functions that control the uBitx . Understanding the functions before
* you start hacking around
*/
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//Ham Band
# define MAX_LIMIT_RANGE 10 //because limited eeprom size
byte useHamBandCount = 0 ; //0 use full range frequency
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byte tuneTXType = 0 ; //0 : use full range, 1 : just Change Dial speed, 2 : just ham band change, but can general band by tune, 3 : only ham band (just support 0, 2 (0.26 version))
//100 : use full range but not TX on general band, 101 : just change dial speed but.. 2 : jut... but.. 3 : only ham band (just support 100, 102 (0.26 version))
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unsigned int hamBandRange [ MAX_LIMIT_RANGE ] [ 2 ] ; // = //Khz because reduce use memory
//-1 : not found, 0 ~ 9 : Hamband index
char getIndexHambanBbyFreq ( unsigned long f )
{
f = f / 1000 ;
for ( byte i = 0 ; i < useHamBandCount ; i + + )
if ( hamBandRange [ i ] [ 0 ] < = f & & f < hamBandRange [ i ] [ 1 ] )
return i ;
return - 1 ;
}
//when Band change step = just hamband
//moveDirection : 1 = next, -1 : prior
void setNextHamBandFreq ( unsigned long f , char moveDirection )
{
unsigned long resultFreq = 0 ;
byte loadMode = 0 ;
char findedIndex = getIndexHambanBbyFreq ( f ) ;
if ( findedIndex = = - 1 ) { //out of hamband
f = f / 1000 ;
for ( byte i = 0 ; i < useHamBandCount - 1 ; i + + ) {
if ( hamBandRange [ i ] [ 1 ] < = f & & f < hamBandRange [ i + 1 ] [ 0 ] ) {
findedIndex = i + moveDirection ;
//return (unsigned long)(hamBandRange[i + 1][0]) * 1000;
}
} //end of for
}
else if ( ( ( moveDirection = = 1 ) & & ( findedIndex < useHamBandCount - 1 ) ) | | //Next
( ( moveDirection = = - 1 ) & & ( findedIndex > 0 ) ) ) { //Prior
findedIndex + = moveDirection ;
}
else
findedIndex = - 1 ;
if ( findedIndex = = - 1 )
findedIndex = ( moveDirection = = 1 ? 0 : useHamBandCount - 1 ) ;
EEPROM . get ( HAM_BAND_FREQS + 4 * findedIndex , resultFreq ) ;
loadMode = ( byte ) ( resultFreq > > 30 ) ;
resultFreq = resultFreq & 0x3FFFFFFF ;
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if ( ( resultFreq / 1000 ) < hamBandRange [ ( unsigned char ) findedIndex ] [ 0 ] | | ( resultFreq / 1000 ) > hamBandRange [ ( unsigned char ) findedIndex ] [ 1 ] )
resultFreq = ( unsigned long ) ( hamBandRange [ ( unsigned char ) findedIndex ] [ 0 ] ) * 1000 ;
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setFrequency ( resultFreq ) ;
byteWithFreqToMode ( loadMode ) ;
}
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void saveBandFreqByIndex ( unsigned long f , unsigned long mode , char bandIndex ) {
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if ( bandIndex > = 0 )
EEPROM . put ( HAM_BAND_FREQS + 4 * bandIndex , ( f & 0x3FFFFFFF ) | ( mode < < 30 ) ) ;
}
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/*
KD8CEC
When using the basic delay of the Arduino , the program freezes .
When the delay is used , the program will generate an error because it is not communicating ,
so Create a new delay function that can do background processing .
*/
unsigned long delayBeforeTime = 0 ;
byte delay_background ( unsigned delayTime , byte fromType ) { //fromType : 4 autoCWKey -> Check Paddle
delayBeforeTime = millis ( ) ;
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while ( millis ( ) - delayBeforeTime < = delayTime ) {
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if ( fromType = = 4 )
{
//CHECK PADDLE
if ( getPaddle ( ) ! = 0 ) //Interrupt : Stop cw Auto mode by Paddle -> Change Auto to Manual
return 1 ;
//Check PTT while auto Sending
autoSendPTTCheck ( ) ;
Check_Cat ( 3 ) ;
}
else
{
//Background Work
Check_Cat ( fromType ) ;
}
}
return 0 ;
}
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/**
* Select the properly tx harmonic filters
* The four harmonic filters use only three relays
* the four LPFs cover 30 - 21 Mhz , 18 - 14 Mhz , 7 - 10 MHz and 3.5 to 5 Mhz
* Briefly , it works like this ,
* - When KT1 is OFF , the ' off ' position routes the PA output through the 30 MHz LPF
* - When KT1 is ON , it routes the PA output to KT2 . Which is why you will see that
* the KT1 is on for the three other cases .
* - When the KT1 is ON and KT2 is off , the off position of KT2 routes the PA output
* to 18 MHz LPF ( That also works for 14 Mhz )
* - When KT1 is On , KT2 is On , it routes the PA output to KT3
* - KT3 , when switched on selects the 7 - 10 Mhz filter
* - KT3 when switched off selects the 3.5 - 5 Mhz filter
* See the circuit to understand this
*/
void setTXFilters ( unsigned long freq ) {
if ( freq > 21000000L ) { // the default filter is with 35 MHz cut-off
digitalWrite ( TX_LPF_A , 0 ) ;
digitalWrite ( TX_LPF_B , 0 ) ;
digitalWrite ( TX_LPF_C , 0 ) ;
}
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
digitalWrite ( TX_LPF_A , 1 ) ;
digitalWrite ( TX_LPF_B , 0 ) ;
digitalWrite ( TX_LPF_C , 0 ) ;
}
else if ( freq > 7000000L ) {
digitalWrite ( TX_LPF_A , 1 ) ;
digitalWrite ( TX_LPF_B , 1 ) ;
digitalWrite ( TX_LPF_C , 0 ) ;
}
else {
digitalWrite ( TX_LPF_A , 1 ) ;
digitalWrite ( TX_LPF_B , 1 ) ;
digitalWrite ( TX_LPF_C , 1 ) ;
}
}
/**
* This is the most frequently called function that configures the
* radio to a particular frequeny , sideband and sets up the transmit filters
*
* The transmit filter relays are powered up only during the tx so they dont
* draw any current during rx .
*
* The carrier oscillator of the detector / modulator is permanently fixed at
* uppper sideband . The sideband selection is done by placing the second oscillator
* either 12 Mhz below or above the 45 Mhz signal thereby inverting the sidebands
* through mixing of the second local oscillator .
*/
void setFrequency ( unsigned long f ) {
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f = ( f / arTuneStep [ tuneStepIndex - 1 ] ) * arTuneStep [ tuneStepIndex - 1 ] ;
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setTXFilters ( f ) ;
if ( isUSB ) {
si5351bx_setfreq ( 2 , SECOND_OSC_USB - usbCarrier + f ) ;
si5351bx_setfreq ( 1 , SECOND_OSC_USB ) ;
}
else {
si5351bx_setfreq ( 2 , SECOND_OSC_LSB + usbCarrier + f ) ;
si5351bx_setfreq ( 1 , SECOND_OSC_LSB ) ;
}
frequency = f ;
}
/**
* startTx is called by the PTT , cw keyer and CAT protocol to
* put the uBitx in tx mode . It takes care of rit settings , sideband settings
* Note : In cw mode , doesnt key the radio , only puts it in tx mode
*/
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void startTx ( byte txMode , byte isDisplayUpdate ) {
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//Check Hamband only TX //Not found Hamband index by now frequency
if ( tuneTXType > = 100 & & getIndexHambanBbyFreq ( ritOn ? ritTxFrequency : frequency ) = = - 1 ) {
//no message
return ;
}
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if ( ( isTxType & 0x01 ) ! = 0x01 )
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digitalWrite ( TX_RX , 1 ) ;
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inTx = 1 ;
if ( ritOn ) {
//save the current as the rx frequency
ritRxFrequency = frequency ;
setFrequency ( ritTxFrequency ) ;
}
if ( txMode = = TX_CW ) {
//turn off the second local oscillator and the bfo
si5351bx_setfreq ( 0 , 0 ) ;
si5351bx_setfreq ( 1 , 0 ) ;
//shif the first oscillator to the tx frequency directly
//the key up and key down will toggle the carrier unbalancing
//the exact cw frequency is the tuned frequency + sidetone
if ( isUSB )
si5351bx_setfreq ( 2 , frequency + sideTone ) ;
else
si5351bx_setfreq ( 2 , frequency - sideTone ) ;
}
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//reduce latency time when begin of CW mode
if ( isDisplayUpdate = = 1 )
updateDisplay ( ) ;
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}
void stopTx ( ) {
inTx = 0 ;
digitalWrite ( TX_RX , 0 ) ; //turn off the tx
si5351bx_setfreq ( 0 , usbCarrier ) ; //set back the carrier oscillator anyway, cw tx switches it off
if ( ritOn )
setFrequency ( ritRxFrequency ) ;
else
setFrequency ( frequency ) ;
updateDisplay ( ) ;
}
/**
* ritEnable is called with a frequency parameter that determines
* what the tx frequency will be
*/
void ritEnable ( unsigned long f ) {
ritOn = 1 ;
//save the non-rit frequency back into the VFO memory
//as RIT is a temporary shift, this is not saved to EEPROM
ritTxFrequency = f ;
}
// this is called by the RIT menu routine
void ritDisable ( ) {
if ( ritOn ) {
ritOn = 0 ;
setFrequency ( ritTxFrequency ) ;
updateDisplay ( ) ;
}
}
/**
* Basic User Interface Routines . These check the front panel for any activity
*/
/**
* The PTT is checked only if we are not already in a cw transmit session
* If the PTT is pressed , we shift to the ritbase if the rit was on
* flip the T / R line to T and update the display to denote transmission
*/
void checkPTT ( ) {
//we don't check for ptt when transmitting cw
if ( cwTimeout > 0 )
return ;
if ( digitalRead ( PTT ) = = 0 & & inTx = = 0 ) {
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startTx ( TX_SSB , 1 ) ;
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delay ( 50 ) ; //debounce the PTT
}
if ( digitalRead ( PTT ) = = 1 & & inTx = = 1 )
stopTx ( ) ;
}
void checkButton ( ) {
//only if the button is pressed
if ( ! btnDown ( ) )
return ;
delay ( 50 ) ;
if ( ! btnDown ( ) ) //debounce
return ;
doMenu ( ) ;
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//wait for the button to go up again
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while ( btnDown ( ) ) {
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delay ( 10 ) ;
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Check_Cat ( 0 ) ;
}
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delay ( 50 ) ; //debounce
}
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/************************************
Replace function by KD8CEC
prevent error controls
applied Threshold for reduct errors , dial Lock , dynamic Step
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
byte threshold = 2 ; //noe action for count
unsigned long lastEncInputtime = 0 ;
int encodedSumValue = 0 ;
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unsigned long lastTunetime = 0 ; //if continous moving, skip threshold processing
byte lastMovedirection = 0 ; //0 : stop, 1 : cw, 2 : ccw
# define skipThresholdTime 100
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# define encodeTimeOut 1000
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void doTuningWithThresHold ( ) {
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int s = 0 ;
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unsigned long prev_freq ;
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long incdecValue = 0 ;
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if ( ( vfoActive = = VFO_A & & ( ( isDialLock & 0x01 ) = = 0x01 ) ) | |
( vfoActive = = VFO_B & & ( ( isDialLock & 0x02 ) = = 0x02 ) ) )
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return ;
if ( isCWAutoMode = = 0 | | cwAutoDialType = = 1 )
s = enc_read ( ) ;
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//if time is exceeded, it is recognized as an error,
//ignore exists values, because of errors
if ( s = = 0 ) {
if ( encodedSumValue ! = 0 & & ( millis ( ) - encodeTimeOut ) > lastEncInputtime )
encodedSumValue = 0 ;
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lastMovedirection = 0 ;
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return ;
}
lastEncInputtime = millis ( ) ;
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//for check moving direction
encodedSumValue + = ( s > 0 ? 1 : - 1 ) ;
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//check threshold and operator actions (hold dial speed = continous moving, skip threshold check)
if ( ( lastTunetime < millis ( ) - skipThresholdTime ) & & ( ( encodedSumValue * encodedSumValue ) < = ( threshold * threshold ) ) )
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return ;
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lastTunetime = millis ( ) ;
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//Valid Action without noise
encodedSumValue = 0 ;
prev_freq = frequency ;
//incdecValue = tuningStep * s;
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frequency + = ( arTuneStep [ tuneStepIndex - 1 ] * s * ( s * s < 10 ? 1 : 3 ) ) ; //appield weight (s is speed)
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if ( prev_freq < 10000000l & & frequency > 10000000l )
isUSB = true ;
if ( prev_freq > 10000000l & & frequency < 10000000l )
isUSB = false ;
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setFrequency ( frequency ) ;
updateDisplay ( ) ;
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}
/**
* RIT only steps back and forth by 100 hz at a time
*/
void doRIT ( ) {
int knob = enc_read ( ) ;
unsigned long old_freq = frequency ;
if ( knob < 0 )
frequency - = 100l ;
else if ( knob > 0 )
frequency + = 100 ;
if ( old_freq ! = frequency ) {
setFrequency ( frequency ) ;
updateDisplay ( ) ;
}
}
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/**
save Frequency and mode to eeprom
*/
void storeFrequencyAndMode ( byte saveType )
{
//freqType : 0 Both (vfoA and vfoB), 1 : vfoA, 2 : vfoB
if ( saveType = = 0 | | saveType = = 1 ) //vfoA
{
if ( vfoA ! = vfoA_eeprom ) {
EEPROM . put ( VFO_A , vfoA ) ;
vfoA_eeprom = vfoA ;
}
if ( vfoA_mode ! = vfoA_mode_eeprom ) {
EEPROM . put ( VFO_A_MODE , vfoA_mode ) ;
vfoA_mode_eeprom = vfoA_mode ;
}
}
if ( saveType = = 0 | | saveType = = 2 ) //vfoB
{
if ( vfoB ! = vfoB_eeprom ) {
EEPROM . put ( VFO_B , vfoB ) ;
vfoB_eeprom = vfoB ;
}
if ( vfoB_mode ! = vfoB_mode_eeprom ) {
EEPROM . put ( VFO_B_MODE , vfoB_mode ) ;
vfoB_mode_eeprom = vfoB_mode ;
}
}
}
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/**
* The settings are read from EEPROM . The first time around , the values may not be
* present or out of range , in this case , some intelligent defaults are copied into the
* variables .
*/
void initSettings ( ) {
//read the settings from the eeprom and restore them
//if the readings are off, then set defaults
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//for original source Section ===========================
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EEPROM . get ( MASTER_CAL , calibration ) ;
EEPROM . get ( USB_CAL , usbCarrier ) ;
EEPROM . get ( VFO_A , vfoA ) ;
EEPROM . get ( VFO_B , vfoB ) ;
EEPROM . get ( CW_SIDETONE , sideTone ) ;
EEPROM . get ( CW_SPEED , cwSpeed ) ;
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//End of original code
//----------------------------------------------------------------
//Add Lines by KD8CEC
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//for custom source Section =============================
//ID & Version Check from EEProm
//if found different firmware, erase eeprom (32
# define FIRMWAR_ID_ADDR 776 //776 : 0x59, 777 :0x58, 778 : 0x68 : Id Number, if not found id, erase eeprom(32~1023) for prevent system error.
if ( EEPROM . read ( FIRMWAR_ID_ADDR ) ! = 0x59 | |
EEPROM . read ( FIRMWAR_ID_ADDR + 1 ) ! = 0x58 | |
EEPROM . read ( FIRMWAR_ID_ADDR + 2 ) ! = 0x68 ) {
printLineF ( 1 , F ( " Init EEProm... " ) ) ;
//initial all eeprom
for ( unsigned int i = 32 ; i < 1024 ; i + + ) //protect Master_cal, usb_cal
EEPROM . write ( i , 0 ) ;
//Write Firmware ID
EEPROM . write ( FIRMWAR_ID_ADDR , 0x59 ) ;
EEPROM . write ( FIRMWAR_ID_ADDR + 1 , 0x58 ) ;
EEPROM . write ( FIRMWAR_ID_ADDR + 2 , 0x68 ) ;
}
//Version Write for Memory Management Software
if ( EEPROM . read ( VERSION_ADDRESS ) ! = VERSION_NUM )
EEPROM . write ( VERSION_ADDRESS , VERSION_NUM ) ;
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//for Save VFO_A_MODE to eeprom
//0: default, 1:not use, 2:LSB, 3:USB, 4:CW, 5:AM, 6:FM
EEPROM . get ( VFO_A_MODE , vfoA_mode ) ;
EEPROM . get ( VFO_B_MODE , vfoB_mode ) ;
//CW DelayTime
EEPROM . get ( CW_DELAY , cwDelayTime ) ;
//CW interval between TX and CW Start
EEPROM . get ( CW_START , delayBeforeCWStartTime ) ;
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EEPROM . get ( CW_KEY_TYPE , cwKeyType ) ;
if ( cwKeyType > 2 )
cwKeyType = 0 ;
if ( cwKeyType = = 0 )
Iambic_Key = false ;
else
{
Iambic_Key = true ;
if ( cwKeyType = 1 )
keyerControl & = ~ IAMBICB ;
else
keyerControl | = IAMBICB ;
}
EEPROM . get ( DISPLAY_OPTION1 , displayOption1 ) ;
EEPROM . get ( DISPLAY_OPTION2 , displayOption2 ) ;
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//User callsign information
if ( EEPROM . read ( USER_CALLSIGN_KEY ) = = 0x59 )
userCallsignLength = EEPROM . read ( USER_CALLSIGN_LEN ) ; //MAXIMUM 18 LENGTH
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//Ham Band Count
EEPROM . get ( HAM_BAND_COUNT , useHamBandCount ) ;
EEPROM . get ( TX_TUNE_TYPE , tuneTXType ) ;
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byte findedValidValueCount = 0 ;
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//Read band Information
for ( byte i = 0 ; i < useHamBandCount ; i + + ) {
unsigned int tmpReadValue = 0 ;
EEPROM . get ( HAM_BAND_RANGE + 4 * i , tmpReadValue ) ;
hamBandRange [ i ] [ 0 ] = tmpReadValue ;
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if ( tmpReadValue > 1 & & tmpReadValue < 55000 )
findedValidValueCount + + ;
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EEPROM . get ( HAM_BAND_RANGE + 4 * i + 2 , tmpReadValue ) ;
hamBandRange [ i ] [ 1 ] = tmpReadValue ;
}
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//Check Value Range and default Set for new users
if ( ( 3 < tuneTXType & & tuneTXType < 100 ) | | 103 < tuneTXType | | useHamBandCount < 1 | | findedValidValueCount < 5 )
{
tuneTXType = 2 ;
//if empty band Information, auto insert default region 1 frequency range
//This part is made temporary for people who have difficulty setting up, so can remove it when you run out of memory.
useHamBandCount = 10 ;
hamBandRange [ 0 ] [ 0 ] = 1810 ; hamBandRange [ 0 ] [ 1 ] = 2000 ;
hamBandRange [ 1 ] [ 0 ] = 3500 ; hamBandRange [ 1 ] [ 1 ] = 3800 ;
hamBandRange [ 2 ] [ 0 ] = 5351 ; hamBandRange [ 2 ] [ 1 ] = 5367 ;
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hamBandRange [ 3 ] [ 0 ] = 7000 ; hamBandRange [ 3 ] [ 1 ] = 7300 ; //region 1
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hamBandRange [ 4 ] [ 0 ] = 10100 ; hamBandRange [ 4 ] [ 1 ] = 10150 ;
hamBandRange [ 5 ] [ 0 ] = 14000 ; hamBandRange [ 5 ] [ 1 ] = 14350 ;
hamBandRange [ 6 ] [ 0 ] = 18068 ; hamBandRange [ 6 ] [ 1 ] = 18168 ;
hamBandRange [ 7 ] [ 0 ] = 21000 ; hamBandRange [ 7 ] [ 1 ] = 21450 ;
hamBandRange [ 8 ] [ 0 ] = 24890 ; hamBandRange [ 8 ] [ 1 ] = 24990 ;
hamBandRange [ 9 ] [ 0 ] = 28000 ; hamBandRange [ 9 ] [ 1 ] = 29700 ;
}
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//Read Tuning Step Index, and steps
findedValidValueCount = 0 ;
EEPROM . get ( TUNING_STEP , tuneStepIndex ) ;
for ( byte i = 0 ; i < 5 ; i + + ) {
arTuneStep [ i ] = EEPROM . read ( TUNING_STEP + i + 1 ) ;
if ( arTuneStep [ i ] > = 1 & & arTuneStep [ i ] < 251 ) //Maximum 250 for check valid Value
findedValidValueCount + + ;
}
//Check Value Range and default Set for new users
if ( findedValidValueCount < 5 )
{
//Default Setting
arTuneStep [ 0 ] = 10 ;
arTuneStep [ 1 ] = 20 ;
arTuneStep [ 2 ] = 50 ;
arTuneStep [ 3 ] = 100 ;
arTuneStep [ 4 ] = 200 ;
}
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if ( tuneStepIndex = = 0 ) //New User
tuneStepIndex = 3 ;
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//CW Key ADC Range ======= adjust set value for reduce cw keying error
//by KD8CEC
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unsigned int tmpMostBits = 0 ;
tmpMostBits = EEPROM . read ( CW_ADC_MOST_BIT1 ) ;
cwAdcSTFrom = EEPROM . read ( CW_ADC_ST_FROM ) | ( ( tmpMostBits & 0x03 ) < < 8 ) ;
cwAdcSTTo = EEPROM . read ( CW_ADC_ST_TO ) | ( ( tmpMostBits & 0x0C ) < < 6 ) ;
cwAdcDotFrom = EEPROM . read ( CW_ADC_DOT_FROM ) | ( ( tmpMostBits & 0x30 ) < < 4 ) ;
cwAdcDotTo = EEPROM . read ( CW_ADC_DOT_TO ) | ( ( tmpMostBits & 0xC0 ) < < 2 ) ;
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tmpMostBits = EEPROM . read ( CW_ADC_MOST_BIT2 ) ;
cwAdcDashFrom = EEPROM . read ( CW_ADC_DASH_FROM ) | ( ( tmpMostBits & 0x03 ) < < 8 ) ;
cwAdcDashTo = EEPROM . read ( CW_ADC_DASH_TO ) | ( ( tmpMostBits & 0x0C ) < < 6 ) ;
cwAdcBothFrom = EEPROM . read ( CW_ADC_BOTH_FROM ) | ( ( tmpMostBits & 0x30 ) < < 4 ) ;
cwAdcBothTo = EEPROM . read ( CW_ADC_BOTH_TO ) | ( ( tmpMostBits & 0xC0 ) < < 2 ) ;
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//default Value (for original hardware)
if ( cwAdcSTFrom > = cwAdcSTTo )
{
cwAdcSTFrom = 0 ;
cwAdcSTTo = 50 ;
}
if ( cwAdcBothFrom > = cwAdcBothTo )
{
cwAdcBothFrom = 51 ;
cwAdcBothTo = 300 ;
}
if ( cwAdcDotFrom > = cwAdcDotTo )
{
cwAdcDotFrom = 301 ;
cwAdcDotTo = 600 ;
}
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if ( cwAdcDashFrom > = cwAdcDashTo )
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{
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cwAdcDashFrom = 601 ;
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cwAdcDashTo = 800 ;
}
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//end of CW Keying Variables
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if ( cwDelayTime < 1 | | cwDelayTime > 250 )
cwDelayTime = 60 ;
if ( vfoA_mode < 2 )
vfoA_mode = 2 ;
if ( vfoB_mode < 2 )
vfoB_mode = 3 ;
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//original code with modified by kd8cec
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if ( usbCarrier > 12010000l | | usbCarrier < 11990000l )
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usbCarrier = 11995000l ;
if ( vfoA > 35000000l | | 3500000l > vfoA ) {
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vfoA = 7150000l ;
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vfoA_mode = 2 ;
}
if ( vfoB > 35000000l | | 3500000l > vfoB ) {
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vfoB = 14150000l ;
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vfoB_mode = 3 ;
}
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//end of original code section
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//for protect eeprom life by KD8CEC
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vfoA_eeprom = vfoA ;
vfoB_eeprom = vfoB ;
vfoA_mode_eeprom = vfoA_mode ;
vfoB_mode_eeprom = vfoB_mode ;
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if ( sideTone < 100 | | 2000 < sideTone )
sideTone = 800 ;
if ( cwSpeed < 10 | | 1000 < cwSpeed )
cwSpeed = 100 ;
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if ( sideTone < 300 | | sideTone > 1000 ) {
sideTonePitch = 0 ;
sideToneSub = 0 ; ;
}
else {
sideTonePitch = ( sideTone - 300 ) / 50 ;
sideToneSub = sideTone % 50 ;
}
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}
void initPorts ( ) {
analogReference ( DEFAULT ) ;
//??
pinMode ( ENC_A , INPUT_PULLUP ) ;
pinMode ( ENC_B , INPUT_PULLUP ) ;
pinMode ( FBUTTON , INPUT_PULLUP ) ;
//configure the function button to use the external pull-up
// pinMode(FBUTTON, INPUT);
// digitalWrite(FBUTTON, HIGH);
pinMode ( PTT , INPUT_PULLUP ) ;
pinMode ( ANALOG_KEYER , INPUT_PULLUP ) ;
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pinMode ( ANALOG_SMETER , INPUT ) ; //by KD8CEC
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pinMode ( CW_TONE , OUTPUT ) ;
digitalWrite ( CW_TONE , 0 ) ;
pinMode ( TX_RX , OUTPUT ) ;
digitalWrite ( TX_RX , 0 ) ;
pinMode ( TX_LPF_A , OUTPUT ) ;
pinMode ( TX_LPF_B , OUTPUT ) ;
pinMode ( TX_LPF_C , OUTPUT ) ;
digitalWrite ( TX_LPF_A , 0 ) ;
digitalWrite ( TX_LPF_B , 0 ) ;
digitalWrite ( TX_LPF_C , 0 ) ;
pinMode ( CW_KEY , OUTPUT ) ;
digitalWrite ( CW_KEY , 0 ) ;
}
void setup ( )
{
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/*
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//Init EEProm for Fault EEProm TEST and Factory Reset
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//please remove remark for others.
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//for (int i = 0; i < 1024; i++)
for ( int i = 16 ; i < 1024 ; i + + ) //protect Master_cal, usb_cal
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EEPROM . write ( i , 0xFF ) ;
lcd . begin ( 16 , 2 ) ;
printLineF ( 1 , F ( " Complete Erase " ) ) ;
sleep ( 1000 ) ;
//while(1);
//end section of test
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*/
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//Serial.begin(9600);
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lcd . begin ( 16 , 2 ) ;
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printLineF ( 1 , F ( " CECBT v0.31 " ) ) ;
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Init_Cat ( 38400 , SERIAL_8N1 ) ;
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initMeter ( ) ; //not used in this build
initSettings ( ) ;
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if ( userCallsignLength > 0 & & ( ( userCallsignLength & 0x80 ) = = 0x80 ) ) {
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userCallsignLength = userCallsignLength & 0x7F ;
printLineFromEEPRom ( 0 , 0 , 0 , userCallsignLength - 1 ) ; //eeprom to lcd use offset (USER_CALLSIGN_DAT)
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delay ( 500 ) ;
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}
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else {
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printLineF ( 0 , F ( " uBITX v0.20 " ) ) ;
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delay ( 500 ) ;
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clearLine2 ( ) ;
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}
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initPorts ( ) ;
initOscillators ( ) ;
frequency = vfoA ;
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saveCheckFreq = frequency ; //for auto save frequency
byteToMode ( vfoA_mode ) ;
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setFrequency ( vfoA ) ;
updateDisplay ( ) ;
if ( btnDown ( ) )
factory_alignment ( ) ;
}
/**
* The loop checks for keydown , ptt , function button and tuning .
*/
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//for debug
int dbgCnt = 0 ;
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byte flasher = 0 ;
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void checkAutoSaveFreqMode ( )
{
//when tx or ritOn, disable auto save
if ( inTx | | ritOn )
return ;
//detect change frequency
if ( saveCheckFreq ! = frequency )
{
saveCheckTime = millis ( ) ;
saveCheckFreq = frequency ;
}
else if ( saveCheckTime ! = 0 )
{
//check time for Frequency auto save
if ( millis ( ) - saveCheckTime > saveIntervalSec * 1000 )
{
if ( vfoActive = = VFO_A )
{
vfoA = frequency ;
vfoA_mode = modeToByte ( ) ;
storeFrequencyAndMode ( 1 ) ;
}
else
{
vfoB = frequency ;
vfoB_mode = modeToByte ( ) ;
storeFrequencyAndMode ( 2 ) ;
}
}
}
}
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void loop ( ) {
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if ( isCWAutoMode = = 0 ) { //when CW AutoKey Mode, disable this process
if ( ! txCAT )
checkPTT ( ) ;
checkButton ( ) ;
}
else
controlAutoCW ( ) ;
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cwKeyer ( ) ;
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//tune only when not tranmsitting
if ( ! inTx ) {
if ( ritOn )
doRIT ( ) ;
else
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doTuningWithThresHold ( ) ;
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if ( isCWAutoMode = = 0 & & beforeIdle_ProcessTime < millis ( ) - 500 ) {
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idle_process ( ) ;
beforeIdle_ProcessTime = millis ( ) ;
}
} //end of check TX Status
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//we check CAT after the encoder as it might put the radio into TX
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Check_Cat ( inTx ? 1 : 0 ) ;
checkAutoSaveFreqMode ( ) ;
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}