Merge pull request #4 from phdlee/beta0.25

beta 0.25 commit
2018-01-10 11:39:15 +09:00
10 changed files with 456 additions and 2028 deletions
--- a/README.md
+++ b/README.md
@@ -1,67 +1,11 @@
 #IMPORTANT INFORMATION
 ----------------------------------------------------------------------------
 - Beta 0.26 and Beta 0.261, Beta 0.262, Beta 0.27 is complete test
 - You can download and use it.
 #NOTICE
 ----------------------------------------------------------------------------
 I received uBITX a month ago and found that many features are required, and began coding with the idea of implementing minimal functionality as a general hf transceiver rather than an experimental device.
 - fixed bugs...
 - Diallock for uBITX's sensitive encoders
 - built in softare Memory keyer and cw options control for CW communication
 - Implementation of CAT communication protocol for Digital Communication (as FT8, JT65, etc)
 - Delay Options for external Linear.
 - and more...
 Most of the basic functions of the HF transceiver I thought were implemented.
 The minimum basic specification for uBITX to operate as a radio, I think it is finished.
 So I will release the 0.27 version and if I do not see the bug anymore, I will try to change the version name to 1.0.
 Now uBITX is an HF radio and will be able to join you in your happy hams life.
 Based on this source, you can use it by adding functions.
 I am going to do a new project based on this source, linking with WSPR, WSJT-X and so on.
 Of course, this repository is still running. If you have any bugs or ideas, please feel free to email me.
 http://www.hamskey.com
 DE KD8CEC
 kd8cec@gmail.com
 #uBITX
 uBITX firmware, written for the Raduino/Arduino control of uBITX transceivers
 This project is based on https://github.com/afarhan/ubitx and all copyright is inherited.
 The copyright information of the original is below.
 KD8CEC
 ----------------------------------------------------------------------------
 Prepared or finished tasks for the next version
  - Most of them are implemented and included in version 0.27.
  - User Interface on LCD -> Option by user (not need)
  - Include WSPR Beacone function - (implement other new repository)
    complete experiment
    need solve : Big code size (over 100%, then remove some functions for experment)
                 need replace Si5351 Library (increase risk and need more beta tester)
                 W3PM sent me his wonderful source - using BITX, GPS 
 ----------------------------------------------------------------------------
 ## REVISION RECORD
 0.27 
   (First alpha test version, This will be renamed to the major version 1.0)
 - Dual VFO Dial Lock (vfoA Dial lock)
 - Support Ham band on uBITX
   default Hamband is regeion1 but customize by uBITX Manager Software
 - Advanced ham band options (Tx control) for use in all countries. You can adjust it yourself.   
 - Convenience of band movement
 0.26
  - only Beta tester released & source code share
  - find a bug on none initial eeprom uBITX - Fixed (Check -> initialized & compatible original source code)
  - change the version number 0.26 -> 0.27
  - Prevent overflow bugs
  - bug with linux based Hamlib (raspberry pi), It was perfect for the 0.224 version, but there was a problem for the 0.25 version.  
    On Windows, ham deluxe, wsjt-x, jt65-hf, and fldigi were successfully run. Problem with Raspberry pi.
 0.25
  - Beta Version Released
    http://www.hamskey.com/2018/01/release-beta-version-of-cat-support.html
--- a/ubitx_20/cat_libs.ino
+++ b/ubitx_20/cat_libs.ino
@@ -1,5 +1,4 @@
 /*************************************************************************
  KD8CEC's CAT Library for uBITX and HAM
  This source code is written for uBITX, but it can also be used on other radios.
  The CAT protocol is used by many radios to provide remote control to comptuers through
@@ -109,8 +108,7 @@ void CatSetFreq(byte fromType)
 //#define BCD_LEN 9
 //PROTOCOL : 0x03
 //Computer <-(frequency)-> TRCV CAT_BUFF
-//void CatGetFreqMode(unsigned long freq, byte fromType)
+void CatGetFreqMode(unsigned long freq, byte fromType)
 void CatGetFreqMode(unsigned long freq) //for remove warning messages
 {
  int i;
  byte tmpValue;
@@ -131,40 +129,23 @@ void CatGetFreqMode(unsigned long freq) //for remove warning messages
  }
  //Mode Check
-  if (cwMode == 0)
+  if (isUSB)
-  {
+    CAT_BUFF[4] = CAT_MODE_USB;
    if (isUSB)
      CAT_BUFF[4] = CAT_MODE_USB;
    else
      CAT_BUFF[4] = CAT_MODE_LSB;
  }
  else if (cwMode == 1)
  {
      CAT_BUFF[4] = CAT_MODE_CW;
  }
  else
-  {
+    CAT_BUFF[4] = CAT_MODE_LSB;
      CAT_BUFF[4] = CAT_MODE_CW;
  }
  SendCatData(5);
 }
-//void CatSetSplit(boolean isSplit, byte fromType)
+void CatSetSplit(boolean isSplit, byte fromType)
 void CatSetSplit(boolean isSplit) //for remove warning messages
 {
  if (isSplit)
    splitOn = 1;
  else
    splitOn = 0;
  Serial.write(ACK);
 }
 void CatSetPTT(boolean isPTTOn, byte fromType)
 {
-  //
+  if (fromType == 2 || fromType == 3) {
  if ((!inTx) && (fromType == 2 || fromType == 3)) {
    Serial.write(ACK);  
    return;  
  }
@@ -216,18 +197,12 @@ void CatSetMode(byte tmpMode, byte fromType)
  if (!inTx)
  {
-    if (tmpMode == CAT_MODE_CW)
+    if (tmpMode == CAT_MODE_USB)
    {
      cwMode = 1;
    }
    else if (tmpMode == CAT_MODE_USB)
    {
      cwMode = 0;
      isUSB = true;
    }
    else
    {
      cwMode = 0;
      isUSB = false;
    }
@@ -239,8 +214,7 @@ void CatSetMode(byte tmpMode, byte fromType)
 }
 //Read EEProm by uBITX Manager Software
-//void ReadEEPRom(byte fromType)
+void ReadEEPRom(byte fromType)
 void ReadEEPRom() //for remove warnings.
 {
  //5BYTES
  //CAT_BUFF[0] [1] [2] [3] [4] //4 COMMAND
@@ -263,8 +237,7 @@ void ReadEEPRom() //for remove warnings.
 }
 //Write just proecess 1byes
-//void WriteEEPRom(byte fromType)
+void WriteEEPRom(byte fromType)
 void WriteEEPRom(void)  //for remove warning
 {
  //5BYTES
  uint16_t eepromStartIndex = CAT_BUFF[0] + CAT_BUFF[1] * 256;
@@ -284,8 +257,7 @@ void WriteEEPRom(void)  //for remove warning
  }
 }
-//void ReadEEPRom_FT817(byte fromType)
+void ReadEEPRom_FT817(byte fromType)
 void ReadEEPRom_FT817(void) //for remove warnings
 {
  byte temp0 = CAT_BUFF[0];
  byte temp1 = CAT_BUFF[1];
@@ -385,21 +357,10 @@ void ReadEEPRom_FT817(void) //for remove warnings
      CAT_BUFF[1] = 0xB2;
      break;      case 0x69 : //FM Mic (#29)  Contains 0-100 (decimal) as displayed
    case 0x78 :
-      if (cwMode == 0)
+      if (isUSB)
-      {
+        CAT_BUFF[0] = CAT_MODE_USB;
-        if (isUSB)
+      else
-          CAT_BUFF[0] = CAT_MODE_USB;
+        CAT_BUFF[0] = CAT_MODE_LSB;
        else
          CAT_BUFF[0] = CAT_MODE_LSB;
      }
      else if (cwMode == 1)
      {
          CAT_BUFF[0] = CAT_MODE_CW;
      }
      else if (cwMode == 2)
      {
          CAT_BUFF[0] = CAT_MODE_CW;
      }
      if (CAT_BUFF[0] != 0) CAT_BUFF[0] = 1 << 5;
      break;
@@ -422,7 +383,7 @@ void ReadEEPRom_FT817(void) //for remove warnings
      //7A  6 ? ?
      //7A  7 SPL On/Off  0 = Off, 1 = On
-      CAT_BUFF[0] = (splitOn ? 0xFF : 0x7F);
+      CAT_BUFF[0] = (isSplitOn ? 0xFF : 0x7F);
      break;
    case 0xB3 : //
      CAT_BUFF[0] = 0x00;
@@ -437,7 +398,7 @@ void ReadEEPRom_FT817(void) //for remove warnings
 void WriteEEPRom_FT817(byte fromType)
 {
-  //byte temp0 = CAT_BUFF[0];
+  byte temp0 = CAT_BUFF[0];
  byte temp1 = CAT_BUFF[1];
  CAT_BUFF[0] = 0;
@@ -509,8 +470,8 @@ void WriteEEPRom_FT817(byte fromType)
        sideTone = (sideTonePitch * 50 + 300) + sideToneSub;
        printLineF2(F("Sidetone set! CAT"));
        EEPROM.put(CW_SIDETONE, sideTone);
-        delay(300);                       //If timeout errors occur in the calling software, remove them
+        delay(500);
-        clearLine2();
+        printLine2("");
      }
      break;
@@ -521,9 +482,8 @@ void WriteEEPRom_FT817(byte fromType)
        sideTone = (sideTonePitch * 50 + 300) + sideToneSub;
        printLineF2(F("Sidetone set! CAT"));
        EEPROM.put(CW_SIDETONE, sideTone);
-        delay(300);                   //If timeout errors occur in the calling software, remove them
+        delay(500);
-        clearLine2();
+        printLine2("");
        line2DisplayStatus = 0;
      }
      break;
@@ -542,8 +502,8 @@ void WriteEEPRom_FT817(byte fromType)
      cwDelayTime = CAT_BUFF[2];
      printLineF2(F("CW Speed set!"));
      EEPROM.put(CW_DELAY, cwDelayTime);
-      delay(300);
+      delay(500);
-      clearLine2();
+      printLine2("");
      break;
    case 0x62 : //
      //5-0  CW Speed (4-60 WPM) (#21) From 0 to 38 (HEX) with 0 = 4 WPM and 38 = 60 WPM (1 WPM steps)
@@ -551,8 +511,8 @@ void WriteEEPRom_FT817(byte fromType)
      cwSpeed = 1200 / ((CAT_BUFF[2] & 0x3F) + 4);
      printLineF2(F("CW Speed set!"));
      EEPROM.put(CW_SPEED, cwSpeed);
-      delay(300);
+      delay(500);
-      clearLine2();
+      printLine2("");
      break;
      /*
@@ -611,8 +571,7 @@ void WriteEEPRom_FT817(byte fromType)
  Serial.write(ACK);
 }
-//void CatRxStatus(byte fromType) 
+void CatRxStatus(byte fromType) 
 void CatRxStatus(void)  //for remove warning
 {
  byte sMeterValue = 1;
@@ -632,8 +591,7 @@ void CatRxStatus(void)  //for remove warning
 }
-//void CatTxStatus(byte fromType)
+void CatTxStatus(byte fromType)
 void CatTxStatus(void)  //for remove warning
 {
  boolean isHighSWR = false;
  boolean isSplitOn = false;
@@ -690,6 +648,7 @@ void Check_Cat(byte fromType)
      rxBufferCheckCount = Serial.available();
      rxBufferArriveTime = millis() + CAT_RECEIVE_TIMEOUT;  //Set time for timeout
    }
    return;
  }
@@ -734,11 +693,11 @@ void Check_Cat(byte fromType)
    case 0x02 : //Split On
    case 0x82:  //Split Off
-      CatSetSplit(CAT_BUFF[4] == 0x02);
+      CatSetSplit(CAT_BUFF[4] == 0x02, fromType);
      break;
    case 0x03 :   //Read Frequency and mode
-      CatGetFreqMode(frequency);
+      CatGetFreqMode(frequency, fromType);
      break;
    case 0x07 :   //Set Operating  Mode
@@ -755,24 +714,24 @@ void Check_Cat(byte fromType)
      break;
    case 0xDB:  //Read uBITX EEPROM Data
-      ReadEEPRom(); //Call by uBITX Manager Program
+      ReadEEPRom(fromType); //Call by uBITX Manager Program
      break;
    case 0xBB:  //Read FT-817 EEPROM Data  (for comfirtable)
-      ReadEEPRom_FT817();
+      ReadEEPRom_FT817(fromType);
      break;
    case 0xDC:  //Write uBITX EEPROM Data
-      WriteEEPRom(); //Call by uBITX Manager Program
+      WriteEEPRom(fromType); //Call by uBITX Manager Program
      break;
    case 0xBC:  //Write FT-817 EEPROM Data  (for comfirtable)
      WriteEEPRom_FT817(fromType);
      break;
    case 0xE7 :       //Read RX Status
-      CatRxStatus();
+      CatRxStatus(fromType);
      break;
    case 0xF7:      //Read TX Status
-      CatTxStatus();
+      CatTxStatus(fromType);
      break;
    default:
    /*
--- a/ubitx_20/cw_autokey.ino
+++ b/ubitx_20/cw_autokey.ino
@@ -1,6 +1,4 @@
 /*************************************************************************
  KD8CEC's Memory Keyer for HAM
  This source code is written for All amateur radio operator, 
  I have not had amateur radio communication for a long time. CW has been 
  around for a long time, and I do not know what kind of keyer and keying 
@@ -15,7 +13,6 @@
  I wrote this code myself, so there is no license restriction. 
  So this code allows anyone to write with confidence.
  But keep it as long as the original author of the code.
  DE Ian KD8CEC
 -----------------------------------------------------------------------------
   This program is free software: you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
@@ -211,14 +208,10 @@ void sendCWChar(char cwKeyChar)
        charLength = ((tmpChar >> 6) & 0x03) + 3;
        for (j = 0; j < charLength; j++)
-          sendBuff[j] = (tmpChar << (j + 2)) & 0x80;
+          sendBuff[j] = (tmpChar << j + 2) & 0x80;
        break;
      }
      else
      {
        charLength = 0;
      }
    }
  }
@@ -264,7 +257,7 @@ unsigned long scrollDispayTime = 0;
 #define scrollSpeed 500
 byte displayScrolStep = 0;
-void controlAutoCW(){
+int controlAutoCW(){
    int knob = 0;
    byte i;
@@ -299,11 +292,7 @@ void controlAutoCW(){
          printLineFromEEPRom(0, 2, cwStartIndex + displayScrolStep + CW_DATA_OFSTADJ, cwEndIndex + CW_DATA_OFSTADJ); 
-          byte diplayAutoCWLine = 0;
+          lcd.setCursor(0,0);
          if ((displayOption1 & 0x01) == 0x01)
            diplayAutoCWLine = 1;
          lcd.setCursor(0, diplayAutoCWLine);
          lcd.write(byteToChar(selectedCWTextIndex));
          lcd.write(':');
          isNeedScroll = (cwEndIndex - cwStartIndex) > 14 ? 1 : 0;
@@ -365,11 +354,6 @@ void controlAutoCW(){
        //check interval time, if you want adjust interval between chars, modify below
        if (isAutoCWHold == 0 && (millis() - autoCWbeforeTime > cwSpeed * 3))
        {
          if (!inTx){                                           //if not TX Status, change RX -> TX
            keyDown = 0;
            startTx(TX_CW, 0);  //disable updateDisplay Command for reduce latency time
          }
          sendCWChar(EEPROM.read(CW_AUTO_DATA + autoCWSendCharIndex++));
          if (autoCWSendCharIndex > autoCWSendCharEndIndex) {          //finish auto cw send
--- a/ubitx_20/ubitx_20.ino
+++ b/ubitx_20/ubitx_20.ino
@@ -1,10 +1,4 @@
 /**
 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            -------------------------------------------------------------
 * This source file is under General Public License version 3.
 * 
 * This verision uses a built-in Si5351 library
@@ -84,7 +78,6 @@
 #define PTT   (A3)
 #define ANALOG_KEYER (A6)
 #define ANALOG_SPARE (A7)
 #define ANALOG_SMETER (A7)  //by KD8CEC
 /** 
 * The Raduino board is the size of a standard 16x2 LCD panel. It has three connectors:
@@ -151,41 +144,12 @@ int count = 0;          //to generally count ticks, loops, etc
 #define CW_SPEED 28
 //AT328 has 1KBytes EEPROM
 #define CW_CAL 252
 #define VFO_A_MODE 256
 #define VFO_B_MODE 257
 #define CW_DELAY 258
 #define CW_START 259
 #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
 #define TUNING_STEP    342   //TUNING STEP * 6 (index 1 + STEPS 5)  //1STEP : 
-
+//
 //for reduce cw key error, eeprom address
 #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)
 #define CW_KEY_TYPE      358
 #define DISPLAY_OPTION1  361   //Display Option1
 #define DISPLAY_OPTION2  362   //Display Option2
 #define CHANNEL_FREQ    630   //Channel 1 ~ 20, 1 Channel = 4 bytes
 #define CHANNEL_DESC    710   //Channel 1 ~ 20, 1 Channel = 4 bytes
 #define RESERVE3        770   //Reserve3 between Channel and Firmware id check
 //Check Firmware type and version
 #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.
 #define VERSION_ADDRESS 779   //check Firmware version
 //USER INFORMATION
 #define USER_CALLSIGN_KEY 780   //0x59
@@ -238,11 +202,11 @@ int count = 0;          //to generally count ticks, loops, etc
 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, cwmCarrier;
+unsigned long vfoA=7150000L, vfoB=14200000L, sideTone=800, usbCarrier;
 unsigned long vfoA_eeprom, vfoB_eeprom; //for protect eeprom life
 unsigned long frequency, ritRxFrequency, ritTxFrequency;  //frequency is the current frequency on the dial
-unsigned int cwSpeed = 100; //this is actuall the dot period in milliseconds
+int cwSpeed = 100; //this is actuall the dot period in milliseconds
 extern int32_t calibration;
 //for store the mode in eeprom
@@ -255,6 +219,7 @@ byte saveIntervalSec = 10;  //second
 unsigned long saveCheckTime = 0;
 unsigned long saveCheckFreq = 0;
 bool isSplitOn = false;
 byte cwDelayTime = 60;
 byte delayBeforeCWStartTime = 50;
@@ -263,27 +228,8 @@ byte sideTonePitch=0;
 byte sideToneSub = 0;
 //DialLock
-byte isDialLock = 0;  //000000[0]vfoB [0]vfoA 0Bit : A, 1Bit : B
+byte isDialLock = 0;
-byte isTxType = 0;    //000000[0 - isSplit] [0 - isTXStop]
+byte isTxOff = 0;
 long arTuneStep[5];
 byte tuneStepIndex; //default Value 0, start Offset is 0 because of check new user
 byte displayOption1 = 0;
 byte displayOption2 = 0;
 //CW ADC Range
 int cwAdcSTFrom = 0;
 int cwAdcSTTo = 0;
 int cwAdcDotFrom = 0;
 int cwAdcDotTo = 0;
 int cwAdcDashFrom = 0;
 int cwAdcDashTo = 0;
 int cwAdcBothFrom = 0;
 int cwAdcBothTo = 0;
 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;
 //Variables for auto cw mode
 byte isCWAutoMode = 0;          //0 : none, 1 : CW_AutoMode_Menu_Selection, 2 : CW_AutoMode Sending
@@ -303,13 +249,9 @@ byte userCallsignLength = 0;    //7 : display callsign at system startup, 6~0 :
 */
 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
+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 
 char cwMode = 0;              //compatible original source, and extend mode //if cwMode == 0, mode check : isUSB, cwMode > 0, mode Check : cwMode
                              //iscwMode = 0 : ssbmode, 1 :cwl, 2 : cwu, 3 : cwn (none tx)
                              //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
@@ -317,84 +259,11 @@ 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
 unsigned long beforeIdle_ProcessTime = 0; //for check Idle time
 byte line2DisplayStatus = 0;  //0:Clear, 1 : menu, 1: DisplayFrom Idle, 
 char lcdMeter[17];
 byte isIFShift = 0;     //1 = ifShift, 2 extend
 long ifShiftValue = 0;  //
 /**
 * Below are the basic functions that control the uBitx. Understanding the functions before 
 * you start hacking around
 */
 //Ham Band
 #define MAX_LIMIT_RANGE 10  //because limited eeprom size
 byte useHamBandCount = 0;  //0 use full range frequency
 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))
 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;
  loadMode = (byte)(resultFreq >> 29);
  resultFreq = resultFreq & 0x1FFFFFFF;
  if ((resultFreq / 1000) < hamBandRange[(unsigned char)findedIndex][0] || (resultFreq / 1000) > hamBandRange[(unsigned char)findedIndex][1])
    resultFreq = (unsigned long)(hamBandRange[(unsigned char)findedIndex][0]) * 1000;
  setFrequency(resultFreq);
  byteToMode(loadMode, 1);
 }
 void saveBandFreqByIndex(unsigned long f, unsigned long mode, char bandIndex) {
  if (bandIndex >= 0)
    //EEPROM.put(HAM_BAND_FREQS + 4 * bandIndex, (f & 0x3FFFFFFF) | (mode << 30) );
    EEPROM.put(HAM_BAND_FREQS + 4 * bandIndex, (f & 0x1FFFFFFF) | (mode << 29) );
 }
 /*
  KD8CEC
  When using the basic delay of the Arduino, the program freezes.
@@ -406,7 +275,7 @@ unsigned long delayBeforeTime = 0;
 byte delay_background(unsigned delayTime, byte fromType){ //fromType : 4 autoCWKey -> Check Paddle
  delayBeforeTime = millis();
-  while (millis() - delayBeforeTime <= delayTime) {
+  while (millis() <= delayBeforeTime + delayTime) {
    if (fromType == 4)
    {
@@ -484,31 +353,20 @@ void setTXFilters(unsigned long freq){
 */
 void setFrequency(unsigned long f){
-  f = (f / arTuneStep[tuneStepIndex -1]) * arTuneStep[tuneStepIndex -1];
+  uint64_t osc_f;
  //1 digits discarded
  f = (f / 50) * 50;
  setTXFilters(f);
-  if (cwMode == 0)
+  if (isUSB){
-  {
+    si5351bx_setfreq(2, SECOND_OSC_USB - usbCarrier + f);
-    if (isUSB){
+    si5351bx_setfreq(1, SECOND_OSC_USB);
      si5351bx_setfreq(2, SECOND_OSC_USB - usbCarrier + f  + (isIFShift ? ifShiftValue : 0));
      si5351bx_setfreq(1, SECOND_OSC_USB);
    }
    else{
      si5351bx_setfreq(2, SECOND_OSC_LSB + usbCarrier + f + (isIFShift ? ifShiftValue : 0));
      si5351bx_setfreq(1, SECOND_OSC_LSB);
    }
  }
-  else
+  else{
-  {
+    si5351bx_setfreq(2, SECOND_OSC_LSB + usbCarrier + f);
-    if (cwMode == 1){ //CWL
+    si5351bx_setfreq(1, SECOND_OSC_LSB);
      si5351bx_setfreq(2, SECOND_OSC_LSB + cwmCarrier + f + (isIFShift ? ifShiftValue : 0));
      si5351bx_setfreq(1, SECOND_OSC_LSB);
    }
    else{             //CWU
      si5351bx_setfreq(2, SECOND_OSC_USB - cwmCarrier + f + (isIFShift ? ifShiftValue : 0));
      si5351bx_setfreq(1, SECOND_OSC_USB);
    }
  }
  frequency = f;
@@ -521,13 +379,9 @@ void setFrequency(unsigned long f){
 */
 void startTx(byte txMode, byte isDisplayUpdate){
-  //Check Hamband only TX //Not found Hamband index by now frequency
+  unsigned long tx_freq = 0;
  if (tuneTXType >= 100 && getIndexHambanBbyFreq(ritOn ? ritTxFrequency :  frequency) == -1) {
    //no message
    return;
  }
-  if ((isTxType & 0x01) != 0x01)
+  if (isTxOff != 1)
    digitalWrite(TX_RX, 1);
  inTx = 1;
@@ -537,21 +391,6 @@ void startTx(byte txMode, byte isDisplayUpdate){
    ritRxFrequency = frequency;
    setFrequency(ritTxFrequency);
  }
  else if (splitOn == 1) {
      if (vfoActive == VFO_B) {
        vfoActive = VFO_A;
        frequency = vfoA;
        byteToMode(vfoA_mode, 0);
      }
      else if (vfoActive == VFO_A){
        vfoActive = VFO_B;
        frequency = vfoB;
        byteToMode(vfoB_mode, 0);
      }
      setFrequency(frequency);
  } //end of else
  if (txMode == TX_CW){
    //turn off the second local oscillator and the bfo
@@ -561,22 +400,10 @@ void startTx(byte txMode, byte isDisplayUpdate){
    //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)
-    if (cwMode == 0)
+      si5351bx_setfreq(2, frequency + sideTone);
-    {
+    else
-      if (isUSB)
+      si5351bx_setfreq(2, frequency - sideTone); 
        si5351bx_setfreq(2, frequency + sideTone);
      else
        si5351bx_setfreq(2, frequency - sideTone); 
    }
    else if (cwMode == 1) //CWL
    {
        si5351bx_setfreq(2, frequency - sideTone); 
    }
    else  //CWU
    {
        si5351bx_setfreq(2, frequency + sideTone);
    }
  }
  //reduce latency time when begin of CW mode
@@ -588,28 +415,10 @@ 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 (cwMode == 0)
    si5351bx_setfreq(0, usbCarrier + (isIFShift ? ifShiftValue : 0));  //set back the carrier oscillator anyway, cw tx switches it off
  else
    si5351bx_setfreq(0, cwmCarrier + (isIFShift ? ifShiftValue : 0));  //set back the carrier oscillator anyway, cw tx switches it off
  if (ritOn)
    setFrequency(ritRxFrequency);
  else if (splitOn == 1) {
      //vfo Change
      if (vfoActive == VFO_B){
        vfoActive = VFO_A;
        frequency = vfoA;
        byteToMode(vfoA_mode, 0);
      }
      else if (vfoActive == VFO_A){
        vfoActive = VFO_B;
        frequency = vfoB;
        byteToMode(vfoB_mode, 0);
      }
      setFrequency(frequency);
  } //end of else
  else
    setFrequency(frequency);
@@ -661,6 +470,8 @@ void checkPTT(){
 }
 void checkButton(){
  int i, t1, t2, knob, new_knob;
  //only if the button is pressed
  if (!btnDown())
    return;
@@ -679,72 +490,72 @@ void checkButton(){
 }
-/************************************
+/**
-Replace function by KD8CEC
+ * The tuning jumps by 50 Hz on each step when you tune slowly
-prevent error controls
+ * As you spin the encoder faster, the jump size also increases 
-applied Threshold for reduct errors,  dial Lock, dynamic Step
+ * This way, you can quickly move to another band by just spinning the 
- *************************************/
+ * tuning knob
-byte threshold = 2;  //noe action for count
+ */
 unsigned long lastEncInputtime = 0;
 int encodedSumValue = 0;
 unsigned long lastTunetime = 0; //if continous moving, skip threshold processing
 byte lastMovedirection = 0; //0 : stop, 1 : cw, 2 : ccw
-#define skipThresholdTime 100
+void doTuning(){
 #define encodeTimeOut 1000
 void doTuningWithThresHold(){
  int s = 0;
  unsigned long prev_freq;
  int incdecValue = 0;
-  if ((vfoActive == VFO_A && ((isDialLock & 0x01) == 0x01)) ||
+  if (isDialLock == 1)
    (vfoActive == VFO_B && ((isDialLock & 0x02) == 0x02)))
    return;
  if (isCWAutoMode == 0 || cwAutoDialType == 1)
    s = enc_read();
-  //if time is exceeded, it is recognized as an error,
+  if (s){
-  //ignore exists values, because of errors
+    prev_freq = frequency;
  if (s == 0) {
    if (encodedSumValue != 0 && (millis() - encodeTimeOut) > lastEncInputtime)
      encodedSumValue = 0;
-    lastMovedirection = 0;
+    if (s > 10)
-    return;
+      incdecValue = 200000l;
    if (s > 7)
      incdecValue = 10000l;
    else if (s > 4)
      incdecValue = 1000l;
    else if (s > 2)
      incdecValue = 500;
    else if (s > 0)
      incdecValue =  50l;
    else if (s > -2)
      incdecValue = -50l;
    else if (s > -4)
      incdecValue = -500l;
    else if (s > -7)
      incdecValue = -1000l;
    else if (s > -9)
      incdecValue = -10000l;
    else
      incdecValue = -200000l;
    if (incdecValue > 0 && frequency + incdecValue > HIGHEST_FREQ_DIAL)
        frequency = HIGHEST_FREQ_DIAL;      
    else if (incdecValue < 0 && frequency < -incdecValue + LOWEST_FREQ_DIAL)  //for compute and compare based integer type.
      frequency = LOWEST_FREQ_DIAL;
    else
      frequency += incdecValue;
    if (prev_freq < 10000000l && frequency > 10000000l)
      isUSB = true;
    if (prev_freq > 10000000l && frequency < 10000000l)
      isUSB = false;
    setFrequency(frequency);
    updateDisplay();
  }
  lastEncInputtime = millis();
  //for check moving direction
  encodedSumValue += (s > 0 ? 1 : -1);
  //check threshold and operator actions (hold dial speed = continous moving, skip threshold check)
  if ((lastTunetime < millis() - skipThresholdTime) && ((encodedSumValue *  encodedSumValue) <= (threshold * threshold)))
    return;
  lastTunetime = millis();
  //Valid Action without noise
  encodedSumValue = 0;
  prev_freq = frequency;
  //incdecValue = tuningStep * s;
  frequency += (arTuneStep[tuneStepIndex -1] * s * (s * s < 10 ? 1 : 3));  //appield weight (s is speed)
  if (prev_freq < 10000000l && frequency > 10000000l)
    isUSB = true;
  if (prev_freq > 10000000l && frequency < 10000000l)
    isUSB = false;
  setFrequency(frequency);
  updateDisplay();
 }
 /**
 * RIT only steps back and forth by 100 hz at a time
 */
 void doRIT(){
  unsigned long newFreq;
  int knob = enc_read();
  unsigned long old_freq = frequency;
@@ -758,8 +569,9 @@ void doRIT(){
    updateDisplay();
  }
 }
-/*
+
- save Frequency and mode to eeprom for Auto Save with protected eeprom cycle, by kd8cec
+/**
 save Frequency and mode to eeprom
 */
 void storeFrequencyAndMode(byte saveType)
 {
@@ -791,22 +603,6 @@ void storeFrequencyAndMode(byte saveType)
  }
 }
 //calculate step size from 1 byte, compatible uBITX Manager, by KD8CEC
 unsigned int byteToSteps(byte srcByte) {
    byte powerVal = (byte)(srcByte >> 6);
    unsigned int baseVal = srcByte & 0x3F;
    if (powerVal == 1)
        return baseVal * 10;
    else if (powerVal == 2)
        return baseVal * 100;
    else if (powerVal == 3)
        return baseVal * 1000;
    else
        return baseVal;
 }
 /**
 * 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 
@@ -815,41 +611,12 @@ unsigned int byteToSteps(byte srcByte) {
 void initSettings(){
  //read the settings from the eeprom and restore them
  //if the readings are off, then set defaults
  //for original source Section ===========================
  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);
  //End of original code
  //----------------------------------------------------------------
  //Add Lines by KD8CEC
  //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);
  EEPROM.get(CW_CAL, cwmCarrier);
  //for Save VFO_A_MODE to eeprom
  //0: default, 1:not use, 2:LSB, 3:USB, 4:CW, 5:AM, 6:FM
@@ -861,130 +628,14 @@ void initSettings(){
  //CW interval between TX and CW Start
  EEPROM.get(CW_START, delayBeforeCWStartTime);
  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);
  //User callsign information
  if (EEPROM.read(USER_CALLSIGN_KEY) == 0x59)
    userCallsignLength = EEPROM.read(USER_CALLSIGN_LEN);  //MAXIMUM 18 LENGTH
-  //Ham Band Count
+  //Version Write for Memory Management Software
-  EEPROM.get(HAM_BAND_COUNT, useHamBandCount);
+  if (EEPROM.read(VERSION_ADDRESS) != VERSION_NUM)
-  EEPROM.get(TX_TUNE_TYPE, tuneTXType);
+    EEPROM.write(VERSION_ADDRESS, VERSION_NUM);
  byte findedValidValueCount = 0;
  //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;
    if (tmpReadValue > 1 && tmpReadValue < 55000)
      findedValidValueCount++;
    EEPROM.get(HAM_BAND_RANGE + 4 * i + 2, tmpReadValue);
    hamBandRange[i][1] = tmpReadValue;
  }
  //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 2 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; 
    hamBandRange[3][0] = 7000; hamBandRange[3][1] = 7300;     //region 2
    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; 
  }
  //Read Tuning Step Index, and steps
  findedValidValueCount = 0;
  EEPROM.get(TUNING_STEP, tuneStepIndex);
  for (byte i = 0; i < 5; i++) {
    arTuneStep[i] = byteToSteps(EEPROM.read(TUNING_STEP + i + 1));
    if (arTuneStep[i] >= 1 && arTuneStep[i] <= 60000) //Maximum 650 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;
  }
  if (tuneStepIndex == 0) //New User
    tuneStepIndex = 3;
  //CW Key ADC Range ======= adjust set value for reduce cw keying error
  //by KD8CEC
  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);
  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);
  //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;
  }
  if (cwAdcDashFrom >= cwAdcDashTo)
  {
    cwAdcDashFrom = 601;
    cwAdcDashTo = 800;
  }
  //end of CW Keying Variables
  if (cwDelayTime < 1 || cwDelayTime > 250)
    cwDelayTime = 60;
@@ -995,25 +646,20 @@ void initSettings(){
  if (vfoB_mode < 2)
    vfoB_mode = 3;
  //original code with modified by kd8cec
  if (usbCarrier > 12010000l || usbCarrier < 11990000l)
    usbCarrier = 11995000l;
  if (cwmCarrier > 12010000l || cwmCarrier < 11990000l)
    cwmCarrier = 11995000l;
  if (vfoA > 35000000l || 3500000l > vfoA) {
     vfoA = 7150000l;
-     vfoA_mode = 2; //LSB
+     vfoA_mode = 2;
  }
  if (vfoB > 35000000l || 3500000l > vfoB) {
     vfoB = 14150000l;  
-     vfoB_mode = 3; //USB
+     vfoB_mode = 3;
  }
  //end of original code section
-  //for protect eeprom life by KD8CEC
+  //for protect eeprom life
  vfoA_eeprom = vfoA;
  vfoB_eeprom = vfoB;
  vfoA_mode_eeprom = vfoA_mode;
@@ -1049,7 +695,6 @@ void initPorts(){
  pinMode(PTT, INPUT_PULLUP);
  pinMode(ANALOG_KEYER, INPUT_PULLUP);
  pinMode(ANALOG_SMETER, INPUT); //by KD8CEC
  pinMode(CW_TONE, OUTPUT);  
  digitalWrite(CW_TONE, 0);
@@ -1070,58 +715,141 @@ void initPorts(){
 void setup()
 {
  /*
  //Init EEProm for Fault EEProm TEST and Factory Reset
-  //please remove remark for others.
+  /*
-  //for (int i = 0; i < 1024; i++)
+  for (int i = 0; i < 1024; i++)
-  for (int i = 16; i < 1024; i++) //protect Master_cal, usb_cal
+    EEPROM.write(i, 0);
    EEPROM.write(i, 0xFF);
  lcd.begin(16, 2);
  printLineF(1, F("Complete Erase")); 
  sleep(1000);
  //while(1);
  //end section of test
  */
  //Serial.begin(9600);
  lcd.begin(16, 2);
  printLineF(1, F("CECBT v1.01")); 
  Init_Cat(38400, SERIAL_8N1);
  initMeter(); //not used in this build
  initSettings();
-  if (userCallsignLength > 0 && ((userCallsignLength & 0x80) == 0x80)) {
+  printLineF(1, F("CECBT v0.25")); 
  if (userCallsignLength > 0 && ((userCallsignLength & 0x80) == 0x80))
  {
    userCallsignLength = userCallsignLength & 0x7F;
    printLineFromEEPRom(0, 0, 0, userCallsignLength -1); //eeprom to lcd use offset (USER_CALLSIGN_DAT)
    delay(500);
  }
-  else {
+  else
  {
    printLineF(0, F("uBITX v0.20")); 
-    delay(500);
+    delay_background(500, 0);
-    clearLine2();
+    printLine2(""); 
  }
  initPorts();     
  byteToMode(vfoA_mode, 0);
  initOscillators();
  frequency = vfoA;
  saveCheckFreq = frequency;  //for auto save frequency
  byteToMode(vfoA_mode);
  setFrequency(vfoA);
  updateDisplay();
  if (btnDown())
    factory_alignment();
 /*
   //This is for auto key test
  EEPROM.put(CW_AUTO_MAGIC_KEY, 0x73);        //MAGIC KEY
  EEPROM.put(CW_AUTO_COUNT, 3);               //WORD COUNT
  EEPROM.put(CW_AUTO_DATA + 0, 6);        // 0 word begin postion / CQCQ TEST K
  EEPROM.put(CW_AUTO_DATA + 1, 33);       // 0 word end postion / CQCQ TEST K
  EEPROM.put(CW_AUTO_DATA + 2, 34);       //1 word begin position / LOL LOL
  EEPROM.put(CW_AUTO_DATA + 3, 40);       //1 word end position / LOL LOL
  EEPROM.put(CW_AUTO_DATA + 4, 41);       //2 word begin position / /?![]789
  EEPROM.put(CW_AUTO_DATA + 5, 48);       //2 word end position / /?![]789
  EEPROM.put(CW_AUTO_DATA + 6, 'C');      //
  EEPROM.put(CW_AUTO_DATA + 7, 'Q');      //
  EEPROM.put(CW_AUTO_DATA + 8, 'C');      //
  EEPROM.put(CW_AUTO_DATA + 9, 'Q');      //
  EEPROM.put(CW_AUTO_DATA + 10, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 11, 'D');      //
  EEPROM.put(CW_AUTO_DATA + 12, 'E');      //
  EEPROM.put(CW_AUTO_DATA + 13, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 14, 'K');      //
  EEPROM.put(CW_AUTO_DATA + 15, 'D');      //
  EEPROM.put(CW_AUTO_DATA + 16, '8');      //
  EEPROM.put(CW_AUTO_DATA + 17, 'C');      //
  EEPROM.put(CW_AUTO_DATA + 18, 'E');      //
  EEPROM.put(CW_AUTO_DATA + 19, 'C');      //
  EEPROM.put(CW_AUTO_DATA + 20, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 21, 'E');      //
  EEPROM.put(CW_AUTO_DATA + 22, 'M');      //
  EEPROM.put(CW_AUTO_DATA + 23, '3');      //
  EEPROM.put(CW_AUTO_DATA + 24, '7');      //
  EEPROM.put(CW_AUTO_DATA + 25, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 26, 'D');      //
  EEPROM.put(CW_AUTO_DATA + 27, 'E');      //
  EEPROM.put(CW_AUTO_DATA + 28, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 29, 'C');      //
  EEPROM.put(CW_AUTO_DATA + 30, 'E');      //
  EEPROM.put(CW_AUTO_DATA + 31, 'C');      //
  EEPROM.put(CW_AUTO_DATA + 32, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 33, 'K');      //
 */
 /*
  EEPROM.put(CW_AUTO_DATA + 34, '<');      //
  EEPROM.put(CW_AUTO_DATA + 35, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 36, '>');      //
  EEPROM.put(CW_AUTO_DATA + 37, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 38, '7');      //
  EEPROM.put(CW_AUTO_DATA + 39, '3');      //
  EEPROM.put(CW_AUTO_DATA + 40, 'K');      //
  EEPROM.put(CW_AUTO_DATA + 41, 'C');      //
  EEPROM.put(CW_AUTO_DATA + 42, 'Q');      //
  EEPROM.put(CW_AUTO_DATA + 43, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 44, '>');      // start "
  EEPROM.put(CW_AUTO_DATA + 45, ' ');      // end "
  EEPROM.put(CW_AUTO_DATA + 46, '>');      //
  EEPROM.put(CW_AUTO_DATA + 47, ' ');      //
  EEPROM.put(CW_AUTO_DATA + 48, 'K');      //
 */
 /*
  //This is for auto key test2
  //USER CALL SIGN
  EEPROM.put(USER_CALLSIGN_KEY, 0x59);     //MAGIC KEY
  //EEPROM.put(USER_CALLSIGN_LEN, 10);           //WORD COUNT
  EEPROM.put(USER_CALLSIGN_LEN, 10 + 0x80);           //WORD COUNT
  EEPROM.put(USER_CALLSIGN_DAT + 1, 'K');      //
  EEPROM.put(USER_CALLSIGN_DAT + 2, 'D');      //
  EEPROM.put(USER_CALLSIGN_DAT + 3, '8');      //
  EEPROM.put(USER_CALLSIGN_DAT + 4, 'C');      //
  EEPROM.put(USER_CALLSIGN_DAT + 5, 'E');      //
  EEPROM.put(USER_CALLSIGN_DAT + 6, 'C');      //
  EEPROM.put(USER_CALLSIGN_DAT + 7, '/');      //
  EEPROM.put(USER_CALLSIGN_DAT + 8, 'A');      //
  EEPROM.put(USER_CALLSIGN_DAT + 9, 'B');      //
  EEPROM.put(USER_CALLSIGN_DAT + 10, 'C');      //
  //CW QSO CALLSIGN
  EEPROM.put(CW_STATION_LEN, 6);                //
  EEPROM.put(CW_STATION_LEN - 6 + 0 , 'A');     //
  EEPROM.put(CW_STATION_LEN - 6 + 1 , 'B');     //
  EEPROM.put(CW_STATION_LEN - 6 + 2 , '1');     //
  EEPROM.put(CW_STATION_LEN - 6 + 3 , 'C');     //
  EEPROM.put(CW_STATION_LEN - 6 + 4 , 'D');     //
  EEPROM.put(CW_STATION_LEN - 6 + 5 , 'E');     // 
 */
 }
 /**
 * The loop checks for keydown, ptt, function button and tuning.
 */
 //for debug
 int dbgCnt = 0;
 byte flasher = 0;
 //Auto save Frequency and Mode with Protected eeprom life by KD8CEC
 void checkAutoSaveFreqMode()
 {
  //when tx or ritOn, disable auto save
@@ -1139,7 +867,6 @@ void checkAutoSaveFreqMode()
    //check time for Frequency auto save
    if (millis() - saveCheckTime > saveIntervalSec * 1000)
    {
      /*
      if (vfoActive == VFO_A)
      {
        vfoA = frequency;
@@ -1152,8 +879,6 @@ void checkAutoSaveFreqMode()
        vfoB_mode = modeToByte();
        storeFrequencyAndMode(2);
      }
      */
      FrequencyToVFO(1);
    }
  }
 }
@@ -1173,16 +898,9 @@ void loop(){
  if (!inTx){
    if (ritOn)
      doRIT();
    //else if (isIFShift)
    //  doIFShift();
    else 
-      doTuningWithThresHold();
+      doTuning();
-
+  }
    if (isCWAutoMode == 0 && beforeIdle_ProcessTime < millis() - 250) {
      idle_process();
      beforeIdle_ProcessTime = millis();
    }
  } //end of check TX Status
  //we check CAT after the encoder as it might put the radio into TX
  Check_Cat(inTx? 1 : 0);
--- a/ubitx_20/ubitx_factory_alignment.ino
+++ b/ubitx_20/ubitx_factory_alignment.ino
@@ -14,7 +14,6 @@ void btnWaitForClick(){
 void factory_alignment(){
  factoryCalibration(1);
  line2DisplayStatus = 1;
  if (calibration == 0){
    printLine2("Setup Aborted");
@@ -37,7 +36,6 @@ void factory_alignment(){
  printLine2("#3:Test 3.5MHz");
  cwMode = 0;
  isUSB = false;
  setFrequency(3500000l);
  updateDisplay();
@@ -60,7 +58,6 @@ void factory_alignment(){
  btnWaitForClick();
  printLine2("#5:Test 14MHz");
  cwMode = 0;
  isUSB = true;
  setFrequency(14000000l);
  updateDisplay();
@@ -82,7 +79,6 @@ void factory_alignment(){
  printLine2("Alignment done");
  delay(1000);
  cwMode = 0;
  isUSB = false;
  setFrequency(7150000l);
  updateDisplay();  
--- a/ubitx_20/ubitx_idle.ino
+++ b/ubitx_20/ubitx_idle.ino
@@ -1,259 +0,0 @@
 /*************************************************************************
  KD8CEC's uBITX Idle time Processing
  Functions that run at times that do not affect TX, CW, and CAT
  It is called in 1/10 time unit.
 -----------------------------------------------------------------------------
   This program is free software: you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.
   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.
   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.
 **************************************************************************/
 char line2Buffer[16];
 //KD8CEC 200Hz ST
 //L14.150 200Hz ST
 //U14.150 +150khz
 int freqScrollPosition = 0;
 //Example Line2 Optinal Display
 //immediate execution, not call by scheulder
 void updateLine2Buffer(char isDirectCall)
 {
  unsigned long tmpFreq = 0;
  if (isDirectCall == 0)
  {
    if (ritOn)
    {
      line2Buffer[0] = 'R';
      line2Buffer[1] = 'i';
      line2Buffer[2] = 't';
      line2Buffer[3] = 'T';
      line2Buffer[4] = 'X';
      line2Buffer[5] = ':';
      //display frequency
      tmpFreq = ritTxFrequency;
      for (int i = 15; i >= 6; i--) {
        if (tmpFreq > 0) {
          if (i == 12 || i == 8) line2Buffer[i] = '.';
          else {
            line2Buffer[i] = tmpFreq % 10 + 0x30;
            tmpFreq /= 10;
          }
        }
        else
          line2Buffer[i] = ' ';
      }
      return;
    } //end of ritOn display
    //======================================================
    //other VFO display
    //======================================================
    if (vfoActive == VFO_B)
    {
      tmpFreq = vfoA;
      //line2Buffer[0] = 'A';
    }
    else 
    {
      tmpFreq = vfoB;
      //line2Buffer[0] = 'B';
    }
    // EXAMPLE 1 & 2
    //U14.150.100
    //display frequency
    for (int i = 9; i >= 0; i--) {
      if (tmpFreq > 0) {
        if (i == 2 || i == 6) line2Buffer[i] = '.';
        else {
          line2Buffer[i] = tmpFreq % 10 + 0x30;
          tmpFreq /= 10;
        }
      }
      else
        line2Buffer[i] = ' ';
    }
    //EXAMPLE #1
    if ((displayOption1 & 0x04) == 0x00)  //none scroll display
      line2Buffer[6] = 'k';
    else
    {
      //example #2
      if (freqScrollPosition++ > 18)    //none scroll display time
      {
        line2Buffer[6] = 'k';
        if (freqScrollPosition > 25)
          freqScrollPosition = -1;
      }
      else                              //scroll frequency 
      {
        line2Buffer[10] = 'H';
        line2Buffer[11] = 'z';
        if (freqScrollPosition < 7)   
        {
          for (int i = 11; i >= 0; i--)
            if (i - (7 - freqScrollPosition) >= 0)
              line2Buffer[i] = line2Buffer[i - (7 - freqScrollPosition)];
            else
              line2Buffer[i] = ' ';
        }
        else
        {
          for (int i = 0; i < 11; i++)
            if (i + (freqScrollPosition - 7) <= 11)
              line2Buffer[i] = line2Buffer[i + (freqScrollPosition - 7)];
            else
              line2Buffer[i] = ' ';
        }
      }
    } //scroll
    line2Buffer[7] = ' ';
  } //check direct call by encoder
  if (isIFShift)
  {
    if (isDirectCall == 1)
      for (int i = 0; i < 16; i++)
        line2Buffer[i] = ' ';
      //IFShift Offset Value 
    line2Buffer[8] = 'I';
    line2Buffer[9] = 'F';
    if (ifShiftValue == 0)
    {
      line2Buffer[10] = 'S';
      line2Buffer[11] = ':';
      line2Buffer[12] = 'O';
      line2Buffer[13] = 'F';
      line2Buffer[14] = 'F';
    }
    else
    {
      line2Buffer[10] = ifShiftValue >= 0 ? '+' : 0;
      line2Buffer[11] = 0;
      line2Buffer[12] = ' ';
      //11, 12, 13, 14, 15
      memset(b, 0, sizeof(b));
      ltoa(ifShiftValue, b, DEC);
      strncat(line2Buffer, b, 5);
    }
    if (isDirectCall == 1)  //if call by encoder (not scheduler), immediate print value
        printLine2(line2Buffer);    
  }       // end of display IF
  else    // step display
  {
    if (isDirectCall != 0)
      return;
    memset(&line2Buffer[8], ' ', 8);
    //Step
    long tmpStep = arTuneStep[tuneStepIndex -1];
    byte isStepKhz = 0;
    if (tmpStep >= 1000)
    {
      isStepKhz = 2;
    }
    for (int i = 10; i >= 8 - isStepKhz; i--) {
      if (tmpStep > 0) {
          line2Buffer[i + isStepKhz] = tmpStep % 10 + 0x30;
          tmpStep /= 10;
      }
      else
        line2Buffer[i +isStepKhz] = ' ';
    }
    //if (isStepKhz == 1)
    //  line2Buffer[10] = 'k';
    if (isStepKhz == 0)
    {
      line2Buffer[11] = 'H';
      line2Buffer[12] = 'z';
    }
    line2Buffer[13] = ' ';
    //if (
    //Check CW Key cwKeyType = 0; //0: straight, 1 : iambica, 2: iambicb
    if (cwKeyType == 0)
    {
      line2Buffer[14] = 'S';
      line2Buffer[15] = 'T';
    }
    else if (cwKeyType == 1)
    {
      line2Buffer[14] = 'I';
      line2Buffer[15] = 'A';
    }
    else
    {
      line2Buffer[14] = 'I';
      line2Buffer[15] = 'B';
    }    
  }
 }
 //meterType : 0 = S.Meter, 1 : P.Meter
 void DisplayMeter(byte meterType, byte meterValue, char drawPosition)
 {
  if (meterType == 0 || meterType == 1 || meterType == 2)
  {
    drawMeter(meterValue);  //call original source code
    int lineNumber = 0;
    if ((displayOption1 & 0x01) == 0x01)
      lineNumber = 1;
    lcd.setCursor(drawPosition, lineNumber);
    for (int i = 0; i < 6; i++) //meter 5 + +db 1 = 6
      lcd.write(lcdMeter[i]);
  }
 }
 byte testValue = 0;
 char checkCount = 0;
 void idle_process()
 {
  //space for user graphic display
  if (menuOn == 0)
  {
    if ((displayOption1 & 0x10) == 0x10)    //always empty topline
      return;
    //if line2DisplayStatus == 0 <-- this condition is clear Line, you can display any message
    if (line2DisplayStatus == 0 || (((displayOption1 & 0x04) == 0x04) && line2DisplayStatus == 2)) {
      if (checkCount++ > 1)
      {
        updateLine2Buffer(0); //call by scheduler
        printLine2(line2Buffer);
        line2DisplayStatus = 2;
        checkCount = 0;
      }
      //EX for Meters
      /*
      DisplayMeter(0, testValue++, 7);
      if (testValue > 30)
        testValue = 0;
      */
    }
  }
 }
--- a/ubitx_20/ubitx_keyer.ino
+++ b/ubitx_20/ubitx_keyer.ino
@@ -1,9 +1,6 @@
 /**
- CW Keyer
+ * CW Keyer
- CW Key logic change with ron's code (ubitx_keyer.cpp)
+ * 
 Ron's logic has been modified to work with the original uBITX by KD8CEC
 Original Comment ----------------------------------------------------------------------------
 * The CW keyer handles either a straight key or an iambic / paddle key.
 * They all use just one analog input line. This is how it works.
 * The analog line has the internal pull-up resistor enabled. 
@@ -37,6 +34,7 @@
 //when both are simultaneously pressed
 char lastPaddle = 0;
 //reads the analog keyer pin and reports the paddle
 byte getPaddle(){
  int paddle = analogRead(ANALOG_KEYER);
@@ -83,179 +81,13 @@ void cwKeyUp(){
  cwTimeout = millis() + cwDelayTime * 10;
 }
 //Variables for Ron's new logic
 #define DIT_L 0x01 // DIT latch
 #define DAH_L 0x02 // DAH latch
 #define DIT_PROC 0x04 // DIT is being processed
 #define PDLSWAP 0x08 // 0 for normal, 1 for swap
 #define IAMBICB 0x10 // 0 for Iambic A, 1 for Iambic B
 enum KSTYPE {IDLE, CHK_DIT, CHK_DAH, KEYED_PREP, KEYED, INTER_ELEMENT };
 static unsigned long ktimer;
 unsigned char keyerState = IDLE;
 //Below is a test to reduce the keying error. do not delete lines
 //create by KD8CEC for compatible with new CW Logic
 char update_PaddleLatch(byte isUpdateKeyState) {
  unsigned char tmpKeyerControl = 0;
  int paddle = analogRead(ANALOG_KEYER);
  if (paddle >= cwAdcDashFrom && paddle <= cwAdcDashTo)
    tmpKeyerControl |= DAH_L;
  else if (paddle >= cwAdcDotFrom && paddle <= cwAdcDotTo)
    tmpKeyerControl |= DIT_L;
  else if (paddle >= cwAdcBothFrom && paddle <= cwAdcBothTo)
    tmpKeyerControl |= (DAH_L | DIT_L) ;     
  else 
  {
    if (Iambic_Key)
      tmpKeyerControl = 0 ;
    else if (paddle >= cwAdcSTFrom && paddle <= cwAdcSTTo)
      tmpKeyerControl = DIT_L ;
     else
       tmpKeyerControl = 0 ; 
  }
  if (isUpdateKeyState == 1)
    keyerControl |= tmpKeyerControl;
  return tmpKeyerControl;
 }
 /*****************************************************************************
 // New logic, by RON
 // modified by KD8CEC
 ******************************************************************************/
 void cwKeyer(void){
  lastPaddle = 0;
  bool continue_loop = true;
  unsigned tmpKeyControl = 0;
  if( Iambic_Key ) {
    while(continue_loop) {
      switch (keyerState) {
        case IDLE:
          tmpKeyControl = update_PaddleLatch(0);
          if ( tmpKeyControl == DAH_L || tmpKeyControl == DIT_L || 
            tmpKeyControl == (DAH_L | DIT_L) || (keyerControl & 0x03)) {
             update_PaddleLatch(1);
             keyerState = CHK_DIT;
          }else{
            if (0 < cwTimeout && cwTimeout < millis()){
              cwTimeout = 0;
              stopTx();
            }
            continue_loop = false;
          }
          break;
        case CHK_DIT:
          if (keyerControl & DIT_L) {
            keyerControl |= DIT_PROC;
            ktimer = cwSpeed;
            keyerState = KEYED_PREP;
          }else{
            keyerState = CHK_DAH;
          }
          break;
        case CHK_DAH:
          if (keyerControl & DAH_L) {
            ktimer = cwSpeed*3;
            keyerState = KEYED_PREP;
          }else{
            keyerState = IDLE;
          }
          break;
        case KEYED_PREP:
          ktimer += millis(); // set ktimer to interval end time
          keyerControl &= ~(DIT_L + DAH_L); // clear both paddle latch bits
          keyerState = KEYED; // next state
          if (!inTx){
            keyDown = 0;
            cwTimeout = millis() + cwDelayTime * 10;  //+ CW_TIMEOUT;
            startTx(TX_CW, 1);
          }
          cwKeydown();
          break;
        case KEYED:
          if (millis() > ktimer) { // are we at end of key down ?
           cwKeyUp();
           ktimer = millis() + cwSpeed; // inter-element time
            keyerState = INTER_ELEMENT; // next state
          }else if (keyerControl & IAMBICB) {
            update_PaddleLatch(1); // early paddle latch in Iambic B mode
          }
          break;
        case INTER_ELEMENT:
          // Insert time between dits/dahs
          update_PaddleLatch(1); // latch paddle state
          if (millis() > ktimer) { // are we at end of inter-space ?
            if (keyerControl & DIT_PROC) { // was it a dit or dah ?
              keyerControl &= ~(DIT_L + DIT_PROC); // clear two bits
              keyerState = CHK_DAH; // dit done, check for dah
            }else{
              keyerControl &= ~(DAH_L); // clear dah latch
              keyerState = IDLE; // go idle
            }
          }
          break;
      }
      Check_Cat(2);
    } //end of while
  }
  else{
    while(1){
      if (update_PaddleLatch(0) == DIT_L) {
        // if we are here, it is only because the key is pressed
        if (!inTx){
          keyDown = 0;
          cwTimeout = millis() + cwDelayTime * 10;  //+ CW_TIMEOUT; 
          startTx(TX_CW, 1);
        }
        cwKeydown();
        while ( update_PaddleLatch(0) == DIT_L ) 
          delay_background(1, 3);
        cwKeyUp();
      }
      else{
        if (0 < cwTimeout && cwTimeout < millis()){
          cwTimeout = 0;
          keyDown = 0;
          stopTx();
        }
        if (!cwTimeout)
          return;
        // got back to the beginning of the loop, if no further activity happens on straight key
        // we will time out, and return out of this routine 
        //delay(5);
        delay_background(5, 3);
        continue;
      }
      Check_Cat(2);
    } //end of while
  }   //end of elese
 }
 //=======================================================================================
 //Before logic
 //by Farhan and modified by KD8CEC
 //======================================================================================
 /**
 * The keyer handles the straight key as well as the iambic key
 * This module keeps looping until the user stops sending cw
 * if the cwTimeout is set to 0, then it means, we have to exit the keyer loop
 * Each time the key is hit the cwTimeout is pushed to a time in the future by cwKeyDown()
 */
- /*
+ 
 void cwKeyer(){
  byte paddle;
  lastPaddle = 0;
@@ -279,7 +111,17 @@ void cwKeyer(){
      if (!cwTimeout)
        return;
-      Check_Cat(2); //for uBITX on Raspberry pi, when straight keying, disconnect / test complete
+      //if a paddle was used (not a straight key) we should extend the space to be a full dash 
      //by adding two more dots long space (one has already been added at the end of the dot or dash)
      /*
      if (cwTimeout > 0 && lastPaddle != PADDLE_STRAIGHT)
        delay_background(cwSpeed * 2, 3);
        //delay(cwSpeed * 2);
      // got back to the begining of the loop, if no further activity happens on the paddle or the straight key
      // we will time out, and return out of this routine 
      delay(5);
      */
      continue;
    }
@@ -342,6 +184,3 @@ void cwKeyer(){
      delay(cwSpeed);
  }
 }
 */
--- a/ubitx_20/ubitx_menu.ino
+++ b/ubitx_20/ubitx_menu.ino
--- a/ubitx_20/ubitx_si5351.ino
+++ b/ubitx_20/ubitx_si5351.ino
@@ -62,7 +62,7 @@ void i2cWriten(uint8_t reg, uint8_t *vals, uint8_t vcnt) {  // write array
 void si5351bx_init() {                  // Call once at power-up, start PLLA
-  uint32_t msxp1;
+  uint8_t reg;  uint32_t msxp1;
  Wire.begin();
  i2cWrite(149, 0);                     // SpreadSpectrum off
  i2cWrite(3, si5351bx_clken);          // Disable all CLK output drivers
@@ -109,11 +109,7 @@ void initOscillators(){
  //initialize the SI5351
  si5351bx_init();
  si5351bx_vcoa = (SI5351BX_XTAL * SI5351BX_MSA) + calibration; // apply the calibration correction factor
-
+  si5351bx_setfreq(0, usbCarrier);
  if (cwMode == 0)
    si5351bx_setfreq(0, usbCarrier + (isIFShift ? ifShiftValue : 0));
 else
    si5351bx_setfreq(0, cwmCarrier + (isIFShift ? ifShiftValue : 0));
 }
--- a/ubitx_20/ubitx_ui.ino
+++ b/ubitx_20/ubitx_ui.ino
@@ -25,8 +25,8 @@ int btnDown(){
 * The current reading of the meter is assembled in the string called meter
 */
 //char meter[17];
 /*
 const PROGMEM uint8_t s_meter_bitmap[] = {
  B00000,B00000,B00000,B00000,B00000,B00100,B00100,B11011,
  B10000,B10000,B10000,B10000,B10100,B10100,B10100,B11011,
@@ -35,18 +35,7 @@ const PROGMEM uint8_t s_meter_bitmap[] = {
  B00010,B00010,B00010,B00010,B00110,B00110,B00110,B11011,
  B00001,B00001,B00001,B00001,B00101,B00101,B00101,B11011
 };
-*/
+PGM_P ps_meter_bitmap = reinterpret_cast<PGM_P>(s_meter_bitmap);
 const PROGMEM uint8_t meters_bitmap[] = {
  B10000,  B10000,  B10000,  B10000,  B10000,  B10000,  B10000,  B10000 ,   //custom 1
  B11000,  B11000,  B11000,  B11000,  B11000,  B11000,  B11000,  B11000 ,   //custom 2
  B11100,  B11100,  B11100,  B11100,  B11100,  B11100,  B11100,  B11100 ,   //custom 3
  B11110,  B11110,  B11110,  B11110,  B11110,  B11110,  B11110,  B11110 ,   //custom 4
  B11111,  B11111,  B11111,  B11111,  B11111,  B11111,  B11111,  B11111 ,   //custom 5
  B01000,  B11100,  B01000,  B00000,  B10111,  B10101,  B10101,  B10111     //custom 6
 };
 PGM_P p_metes_bitmap = reinterpret_cast<PGM_P>(meters_bitmap);
 const PROGMEM uint8_t lock_bitmap[8] = {
  0b01110,
@@ -71,54 +60,38 @@ void initMeter(){
  lcd.createChar(0, tmpbytes);
  for (i = 0; i < 8; i++)
-    tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i);
+    tmpbytes[i] = pgm_read_byte(ps_meter_bitmap + i);
  lcd.createChar(1, tmpbytes);
  for (i = 0; i < 8; i++)
-    tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 8);
+    tmpbytes[i] = pgm_read_byte(ps_meter_bitmap + i + 8);
  lcd.createChar(2, tmpbytes);
  for (i = 0; i < 8; i++)
-    tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 16);
+    tmpbytes[i] = pgm_read_byte(ps_meter_bitmap + i + 16);
  lcd.createChar(3, tmpbytes);
  for (i = 0; i < 8; i++)
-    tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 24);
+    tmpbytes[i] = pgm_read_byte(ps_meter_bitmap + i + 24);
  lcd.createChar(4, tmpbytes);
  for (i = 0; i < 8; i++)
-    tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 32);
+    tmpbytes[i] = pgm_read_byte(ps_meter_bitmap + i + 28);
  lcd.createChar(5, tmpbytes);
  for (i = 0; i < 8; i++)
-    tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 40);
+    tmpbytes[i] = pgm_read_byte(ps_meter_bitmap + i + 32);
  lcd.createChar(6, tmpbytes);
 }
-//by KD8CEC
+/**
-//0 ~ 25 : 30 over : + 10
+ * The meter is drawn with special characters.
-void drawMeter(int needle) {
+ * character 1 is used to simple draw the blocks of the scale of the meter
-  //5Char + O over
+ * characters 2 to 6 are used to draw the needle in positions 1 to within the block
-  int i;
+ * This displays a meter from 0 to 100, -1 displays nothing
 */
-  for (i = 0; i < 5; i++) {
+ /*
    if (needle >= 5)
      lcdMeter[i] = 5; //full
    else if (needle > 0)
      lcdMeter[i] = needle; //full
    else  //0
      lcdMeter[i] = 0x20;
    needle -= 5;
  }
  if (needle > 0)
    lcdMeter[5] = 6;
  else
    lcdMeter[5] = 0x20;
 }
 /*
 void drawMeter(int8_t needle){
  int16_t best, i, s;
@@ -128,23 +101,21 @@ void drawMeter(int8_t needle){
  s = (needle * 4)/10;
  for (i = 0; i < 8; i++){
    if (s >= 5)
-      lcdMeter[i] = 1;
+      meter[i] = 1;
    else if (s >= 0)
-      lcdMeter[i] = 2 + s;
+      meter[i] = 2 + s;
    else
-      lcdMeter[i] = 1;
+      meter[i] = 1;
    s = s - 5;
  }
  if (needle >= 40)
-    lcdMeter[i-1] = 6;
+    meter[i-1] = 6;
-  lcdMeter[i] = 0;
+  meter[i] = 0;
 }
 */
 // The generic routine to display one line on the LCD 
 void printLine(unsigned char linenmbr, const char *c) {
  if ((displayOption1 & 0x01) == 0x01)
    linenmbr = (linenmbr == 0 ? 1 : 0); //Line Toggle
 // The generic routine to display one line on the LCD 
 void printLine(char linenmbr, char *c) {
  if (strcmp(c, printBuff[linenmbr])) {     // only refresh the display when there was a change
    lcd.setCursor(0, linenmbr);             // place the cursor at the beginning of the selected line
    lcd.print(c);
@@ -174,9 +145,6 @@ void printLineF(char linenmbr, const __FlashStringHelper *c)
 #define LCD_MAX_COLUMN 16
 void printLineFromEEPRom(char linenmbr, char lcdColumn, byte eepromStartIndex, byte eepromEndIndex) {
  if ((displayOption1 & 0x01) == 0x01)
    linenmbr = (linenmbr == 0 ? 1 : 0); //Line Toggle
  lcd.setCursor(lcdColumn, linenmbr);
  for (byte i = eepromStartIndex; i <= eepromEndIndex; i++)
@@ -192,20 +160,14 @@ void printLineFromEEPRom(char linenmbr, char lcdColumn, byte eepromStartIndex, b
 }
 //  short cut to print to the first line
-void printLine1(const char *c){
+void printLine1(char *c){
  printLine(1,c);
 }
 //  short cut to print to the first line
-void printLine2(const char *c){
+void printLine2(char *c){
  printLine(0,c);
 }
 void clearLine2()
 {
  printLine2("");
  line2DisplayStatus = 0;
 }
 //  short cut to print to the first line
 void printLine1Clear(){
  printLine(1,"");
@@ -217,7 +179,6 @@ void printLine2Clear(){
 void printLine2ClearAndUpdate(){
  printLine(0, "");
  line2DisplayStatus = 0;  
  updateDisplay();
 }
@@ -233,6 +194,7 @@ char byteToChar(byte srcByte){
 void updateDisplay() {
  // tks Jack Purdum W8TEE
  // replaced fsprint commmands by str commands for code size reduction
  // replace code for Frequency numbering error (alignment, point...) by KD8CEC
  int i;
  unsigned long tmpFreq = frequency; //
@@ -259,21 +221,10 @@ void updateDisplay() {
    if (ritOn)
      strcpy(c, "RIT ");
    else {
-      if (cwMode == 0)
+      if (isUSB)
-      {
+        strcpy(c, "USB ");
        if (isUSB)
          strcpy(c, "USB ");
        else
          strcpy(c, "LSB ");
      }
      else if (cwMode == 1)
      {
          strcpy(c, "CWL ");
      }
      else
-      {
+        strcpy(c, "LSB ");
          strcpy(c, "CWU ");
      }
    }
    if (vfoActive == VFO_A) // VFO A is active
      strcat(c, "A:");
@@ -300,22 +251,17 @@ void updateDisplay() {
  //  strcat(c, " TX");
  printLine(1, c);
-  byte diplayVFOLine = 1;
+  if (isDialLock == 1) {
-  if ((displayOption1 & 0x01) == 0x01)
+    lcd.setCursor(5,1);
    diplayVFOLine = 0;
  if ((vfoActive == VFO_A && ((isDialLock & 0x01) == 0x01)) ||
    (vfoActive == VFO_B && ((isDialLock & 0x02) == 0x02))) {
    lcd.setCursor(5,diplayVFOLine);
    lcd.write((uint8_t)0);
  }
  else if (isCWAutoMode == 2){
-    lcd.setCursor(5,diplayVFOLine);
+    lcd.setCursor(5,1);
    lcd.write(0x7E);
  }
  else
  {
-    lcd.setCursor(5,diplayVFOLine);
+    lcd.setCursor(5,1);
    lcd.write(":");
  }
@@ -365,9 +311,9 @@ int enc_read(void) {
  byte newState;
  int enc_speed = 0;
-  unsigned long start_at = millis();
+  long stop_by = millis() + 50;
-  while (millis() - start_at < 50) { // check if the previous state was stable
+  while (millis() < stop_by) { // check if the previous state was stable
    newState = enc_state(); // Get current state  
    if (newState != enc_prev_state)