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97 Commits
version1.0 ... v1.073

Author SHA1 Message Date
phdlee
5c40718bec Merge pull request #31 from phdlee/version1.073 
Version1.073
 2018-04-24 17:33:58 +09:00
phdlee
6add092391 Extended key (select key type) 2018-04-24 17:26:34 +09:00
phdlee
3b4bdafacc Merge pull request #30 from phdlee/version1.072 
Version1.072
 2018-04-23 21:43:56 +09:00
phdlee
82d9682ee9 Merge branch 'master' into version1.072 2018-04-23 21:43:50 +09:00
phdlee
6be127d811 test lcd 2018-04-23 21:40:45 +09:00
phdlee
5b13ede65b test of extended key and dual lcd 2018-04-23 08:29:19 +09:00
phdlee
0aafe32e27 Added Dual LCD 2018-04-21 16:09:21 +09:00
phdlee
289ae1bd77 Merge pull request #29 from phdlee/version1.071 
Improve receive perforamnce for USB, CWU, custom uBITX
 2018-04-18 20:25:32 +09:00
phdlee
5611e1c0ff lcdtest and extended ubutton tested 2018-04-18 20:22:52 +09:00
phdlee
86797181cf Merge pull request #28 from RichNeese/master 
Tuning step change
 2018-04-18 08:32:53 +09:00
phdlee
f600c18541 add extended Keys (mode, band, tunestep) and i2clcd working 2018-04-17 21:26:29 +09:00
Richard Neese
11b6fbc1f4 Tuning step change 
changed tuning steps to 10/50/100/500/1000
 2018-04-16 21:56:20 -04:00
phdlee
0e245fc488 Add 20x04LCD and S.Meter 2018-04-16 23:56:32 +09:00
phdlee
d721816039 LCD Work step1 2018-04-12 22:08:43 +09:00
phdlee
34be2d0845 Improve receive perforamnce for USB, CWU, custom uBITX 2018-04-09 23:35:13 +09:00
phdlee
0996870154 Merge pull request #27 from phdlee/version1.07 
Version1.07
 2018-04-07 21:33:30 +09:00
phdlee
689cfda09e Add Support SDR Receiver and improve ATT 2018-04-07 21:32:01 +09:00
phdlee
23f1b7cd5c Added IF Tune, ATT, SDR Functions 2018-04-06 21:43:36 +09:00
phdlee
d4ed0589e5 Applied 1602 Tiny LCD Library for reduce program Memory 2018-04-05 22:57:07 +09:00
phdlee
5f906a4497 To Support various LCD Type 2018-04-05 22:16:54 +09:00
phdlee
1210f56cd1 move display routine ui to idle 2018-04-05 21:30:35 +09:00
phdlee
e8d6792073 complete setup menu ui for reduce program memory 2018-04-05 17:36:16 +09:00
phdlee
9c4b694ce2 Update README.md 2018-04-05 10:19:38 +09:00
phdlee
02f22d66e5 Change Menu codes 2018-04-05 09:50:29 +09:00
phdlee
11e47fdccc Added Version Info at top of ubitx_20.ino 2018-04-04 22:20:04 +09:00
phdlee
7aafed9e95 rename ubitx_wspr.cpp to ubitx_wspr.ino 2018-04-04 20:29:27 +09:00
phdlee
5afcdf2583 Update README.md 2018-04-04 20:22:42 +09:00
phdlee
075f585a1e Update README.md 2018-03-29 22:31:36 +09:00
phdlee
d0c04df9d8 Merge pull request #26 from phdlee/version1.06 
Version1.06
 2018-03-25 03:22:29 +09:00
phdlee
dd6d4555a8 Update ubitx_20.ino 2018-03-25 03:21:31 +09:00
phdlee
8f8850f4da Update ubitx_wspr.cpp 2018-03-25 03:17:04 +09:00
phdlee
4e9437a735 Merge pull request #25 from phdlee/version1.06 
Change Version Name
 2018-03-24 21:34:17 +09:00
phdlee
bad62ef728 Change Version Name 2018-03-24 21:33:01 +09:00
phdlee
384c3c41b2 Merge pull request #24 from phdlee/version1.05 
Version1.05
 2018-03-21 14:21:28 +09:00
phdlee
93727e6b22 fixed Cat in IFSifht setup routine 2018-03-21 14:20:09 +09:00
phdlee
31a7f79569 ifshift store, cw mode shift change 2018-03-20 21:41:24 +09:00
phdlee
d7858e35c3 if shift bfo modified 2018-03-20 17:06:28 +09:00
phdlee
ecd104b686 Fixed IF Shift Bug (USB and TX Mode) 2018-03-19 21:35:41 +09:00
phdlee
bd52de59d2 bug fixed (found gereld) Autokey on Rit bug 2018-03-19 10:13:30 +09:00
phdlee
f0409d641d Auto key Bug fixed, LZ1LDO found bug 2018-03-17 11:11:27 +09:00
phdlee
8326b1ade3 bug fixed : cw start delay option 2018-03-15 21:00:42 +09:00
phdlee
94a3e5ca1b Test and some mod about WSPR Calibration 2018-03-13 01:17:06 +09:00
phdlee
a26978f573 Added WSPR and Reduce Program size 2018-03-09 22:02:10 +09:00
phdlee
a21dbe2fa5 Update README.md 2018-03-05 13:03:05 +09:00
phdlee
9faa8bb44c Merge pull request #23 from phdlee/version1.04 
Optimized from Version1.03
 2018-03-05 12:56:55 +09:00
phdlee
d926b15e3d Merge pull request #22 from phdlee/version1.03 
Version1.03
 2018-03-05 12:55:41 +09:00
phdlee
fb2c9d2cc3 Optimized from Version1.03 2018-03-05 12:51:14 +09:00
phdlee
bf68dd6c26 Change Version Number 2018-02-22 13:27:51 +09:00
phdlee
4a6909f361 Change BFO Cal Step(50 to 5), Change CW Frequency Method 2018-02-22 12:26:18 +09:00
phdlee
c911d26163 Merge pull request #21 from phdlee/version1.02 
Version1.02
 2018-02-14 12:11:38 +09:00
phdlee
98e3b41f5a Merge pull request #20 from phdlee/version1.0 
Version1.0
 2018-02-14 12:10:38 +09:00
phdlee
277666f82f Konstantinos (SV1ONW) shared the usage of uBITX Manager on Linux. 
Konstantinos (SV1ONW) shared the usage of uBITX Manager on Linux.
 2018-02-10 18:34:21 +09:00
phdlee
e532dccce7 Update README.md 2018-02-10 15:10:55 +09:00
phdlee
04949cdb93 Update README.md 2018-02-10 13:41:12 +09:00
phdlee
bbdd0947d3 Update README.md 2018-02-10 13:31:51 +09:00
phdlee
a374297d49 Update README.md 2018-02-09 13:42:36 +09:00
phdlee
c1d81d9d5b Update README.md 2018-02-08 01:15:39 +09:00
phdlee
d69588d999 Merge pull request #19 from phdlee/version0.35 
Version0.35
 2018-02-05 16:48:56 +09:00
phdlee
e915c21412 Merge pull request #18 from phdlee/version0.34 
Version0.34
 2018-02-03 17:17:43 +09:00
phdlee
55cfeeb924 Update README.md 2018-01-31 12:13:44 +09:00
phdlee
c8879e0e59 Update README.md 2018-01-31 12:12:58 +09:00
phdlee
4f5ac283b7 Merge pull request #17 from phdlee/version0.33 
Version0.33
 2018-01-31 10:47:20 +09:00
phdlee
3058d52551 Merge pull request #16 from phdlee/version0.32 
Version0.32
 2018-01-30 12:20:18 +09:00
phdlee
04699ba074 Merge pull request #15 from phdlee/version0.31 
Fixed Bug CW Key Range
Append Feature : Display Line Toggle, (Between line1 and line2)
 Append function : for other users / using s.meter, p.meter ... (when idle time execute function)
 2018-01-29 18:44:05 +09:00
phdlee
aa61281c38 Merge pull request #14 from phdlee/version0.296 
rename version to 0.30
 2018-01-27 18:39:22 +09:00
phdlee
261215b1ad Merge pull request #13 from phdlee/version0.296 
Version0.296 => Version 0.30
 2018-01-27 18:36:07 +09:00
phdlee
1a2f5b4fde Update README.md 2018-01-27 18:33:51 +09:00
phdlee
8203427808 Merge pull request #12 from phdlee/version0.296 
Add Comment
 2018-01-26 18:25:48 +09:00
phdlee
4e15f2150c Update README.md 2018-01-25 23:39:33 +09:00
phdlee
82a5fd7df9 Merge pull request #11 from phdlee/version0.296 
Version0.296
 2018-01-25 23:33:04 +09:00
phdlee
386a0b2d46 Update README.md 2018-01-25 22:33:20 +09:00
phdlee
c6401af7d1 Merge pull request #10 from phdlee/version0.29 
Version0.29
 2018-01-25 22:26:19 +09:00
phdlee
b153a305d6 Merge branch 'master' into version0.29 2018-01-25 22:25:35 +09:00
phdlee
e61e45d3dd Update README.md 2018-01-22 18:26:22 +09:00
phdlee
a1f941f965 Update README.md 2018-01-22 18:25:41 +09:00
phdlee
d1e72b3bd5 Update README.md 2018-01-22 18:24:29 +09:00
phdlee
032e7f919f Update README.md 2018-01-22 18:21:55 +09:00
phdlee
b6bc264332 Update README.md 2018-01-22 18:11:15 +09:00
phdlee
b1cc5eb98a Update README.md 2018-01-22 02:11:35 +09:00
phdlee
2fe1662d67 Merge pull request #8 from qiwenmin/master 
Fixed most compilation warnings and a delay issue
 2018-01-20 21:24:15 +09:00
phdlee
ebbc5aae5e Merge pull request #9 from phdlee/version0.28 
change delaytimes via cat
 2018-01-18 11:47:21 +09:00
Qi Wenmin
209cd3a49c Fixed most compilation warnings and a delay issue 
* Fixed most compilation warnings (Compiler warning level: All)
* Fixed a delay issue in enc_read function.
 2018-01-17 14:42:15 +08:00
phdlee
95e5c1dfe5 Update README.md 2018-01-14 14:53:28 +09:00
phdlee
45a8479061 Update README.md 2018-01-14 14:52:58 +09:00
phdlee
a6ad381c24 Update README.md 2018-01-14 14:52:22 +09:00
phdlee
bcf80f851d Update README.md 2018-01-14 14:51:46 +09:00
phdlee
16304efacd Update README.md 2018-01-14 14:51:23 +09:00
phdlee
968024ab73 Merge pull request #7 from phdlee/beta0.26 
Beta0.26
 2018-01-14 14:19:53 +09:00
phdlee
3e60728727 Update README.md 2018-01-13 22:27:23 +09:00
phdlee
9781ef086b Update README.md 2018-01-13 10:58:47 +09:00
phdlee
f27f504ea4 Merge pull request #6 from phdlee/beta0.26 
Beta0.26
 2018-01-12 20:19:09 +09:00
phdlee
2b08a76fbf Update README.md 2018-01-12 10:16:59 +09:00
phdlee
90655e03b8 Update README.md 
add status of project
 2018-01-12 09:51:58 +09:00
phdlee
8551ff1b68 Update README.md 2018-01-11 17:40:00 +09:00
phdlee
5ce94e8e49 Merge pull request #5 from qiwenmin/master 
Fix the delay condition bug when overflow
 2018-01-10 13:51:59 +09:00
Qi Wenmin
7ef9c29fa8 Fix the delay condition bug when overflow 
The original expression will cause bug when overflow.
 2018-01-10 12:00:53 +08:00
phdlee
fda398046e Merge pull request #4 from phdlee/beta0.25 
beta 0.25 commit
 2018-01-10 11:39:15 +09:00
16 changed files with 4534 additions and 1464 deletions
Expand all files Collapse all files

119
README.md
View File

@@ -1,28 +1,18 @@
#IMPORTANT INFORMATION
----------------------------------------------------------------------------
- Beta 0.26 and Beta 0.261, Beta 0.262, Beta 0.27 is complete test
- You can download and use it.
- Now Release Version 1.061 on my blog (http://www.hamskey.com)
- You can download and compiled hex file and uBITX Manager application on my blog (http://www.hamskey.com)
#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
@@ -36,16 +26,105 @@ 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
- Reduce Program size
- uBITX with RTL-SDR
- Direct control for Student
----------------------------------------------------------------------------
## REVISION RECORD
1.07 (Working...)
- Please do not download it yet. The code will continue to change for the time being.
- BetaVersion for Reduce program size
1.061
- Added WSPR
You only need uBITX to use WSPR. No external devices are required.
Added Si5351 module for WSPR
- Update uBITX Manager to Version 1.0
- Reduce program size
for WSPR
for other Module
- Fixed IF Shift Bug
Disable IF Shift on TX
IF shift available in USB mode
Fixed cat routine in IF Shift setup
- Bugs fixed
cw start delay option
Auto key Bug
(found bug : LZ1LDO)
Message selection when Auto Key is used in RIT mode
(found bug : gerald)
- Improve CW Keying (start TX)
1.05
- include 1.05W, 1.051, 1.051W
- for WSPR Beta Test Version
1.04
- Optimized from Version1.03
- Reduce program size (97% -> 95%)
1.03
- Change eBFO Calibration Step (50 to 5)
- Change CW Frequency Display type
1.02
- Applied CW Start Delay to New CW Key logic (This is my mistake when applying the new CW Key Logic.Since uBITX operations are not significantly affected, this does not create a separate Release, It will be reflected in the next release.) - complete
- Modified CW Key Logic for Auto Key, (available AutoKey function by any cw keytype) - complete
- reduce cpu use usage (working)
- reduce (working)
1.01
- Fixed Cat problem with (IAMBIC A or B Selected)
1.0
- rename 0.30 to 1.0
0.35
- vfo to channel bug fixed (not saved mode -> fixed, channel has frequency and mode)
- add Channel tag (ch.1 ~ 10) by uBITX Manager
- add VFO to Channel, Channel To VFO
0.34
- TX Status check in auto Keysend logic
- optimize codes
- change default tune step size, and fixed bug
- change IF shift step (1Hz -> 50Hz)
0.33
- Added CWL, CWU Mode, (dont complete test yet)
- fixed VFO changed bug.
- Added Additional BFO for CWL, CWL
- Added IF Shift
- Change confirmation key PTT -> function key (not critical menus)
- Change CW Key Select type, (toggle -> select by dial)
0.32
- Added function Scroll Frequencty on upper line
- Added Example code for Draw meter and remarked (you can see and use this code in source codes)
- Added Split function, just toggle VFOs when TX/RX
0.31
- Fixed CW ADC Range error
- Display Message on Upper Line (anothor VFO Frequency, Tune Step, Selected Key Type)
0.30
- implemented the function to monitor the value of all analog inputs. This allows you to monitor the status of the CW keys connected to your uBITX.
- possible to set the ADC range for CW Keying. If no setting is made, it will have the same range as the original code. If you set the CW Keying ADC Values using uBITX Manager 0.3, you can reduce the key error.
- Added the function to select Straight Key, IAMBICA, IAMBICB key from the menu.
- default Band select is Ham Band mode, if you want common type, long press function key at band select menu, uBITX Manager can be used to modify frequencies to suit your country.
0.29
- Remove the use of initialization values in BFO settings - using crruent value, if factory reset
- Select Tune Step, default 0, 20, 50, 100, 200, Use the uBITX Manager to set the steps value you want. You can select Step by pressing and holding the Function Key (1sec ~ 2sec).
- Modify Dial Lock Function, Press the Function key for more than 3 seconds to toggle dial lock.
- created a new frequency tune method. remove original source codes, Threshold has been applied to reduce malfunction. checked the continuity of the user operating to make natural tune possible.
- stabilize and remove many warning messages - by Pullrequest and merge
- Changed cw keying method. removed the original code and applied Ron's code and Improved compatibility with original hardware and CAT commnication. It can be used without modification of hardware.
0.28
- Fixed CAT problem with hamlib on Linux
- restore Protocol autorecovery logic
0.27
(First alpha test version, This will be renamed to the major version 1.0)
- Dual VFO Dial Lock (vfoA Dial lock)

50
ubitx_20/cat_libs.ino
View File

@@ -278,7 +278,19 @@ void WriteEEPRom(void) //for remove warning
}
else
{
EEPROM.write(eepromStartIndex, write1Byte);
//Special Command
if (eepromStartIndex == 13131) //Magic Key
{
if (write1Byte == 0x51) //Restart
{
asm volatile (" jmp 0");
}
}
else
{
EEPROM.write(eepromStartIndex, write1Byte);
}
Serial.write(0x77); //OK
Serial.write(ACK);
}
@@ -611,6 +623,34 @@ void WriteEEPRom_FT817(byte fromType)
Serial.write(ACK);
}
const byte anlogPinIndex[6] = {A0, A1, A2, A3, A6, A7};
//Read ADC Value by uBITX Manager Software
void ReadADCValue(void)
{
//ADC MAP for uBITX
int readedADCValue;
//5BYTES
//CAT_BUFF[0] [1] [2] [3] [4] //4 COMMAND
//0 READ ADDRESS
readedADCValue = analogRead(anlogPinIndex[CAT_BUFF[0]]);
CAT_BUFF[0] = readedADCValue >> 8;
CAT_BUFF[1] = readedADCValue;
SendCatData(2);
Serial.write(ACK);
}
void SetIFSValue(void)
{
//Set IFShift Value
isIFShift = CAT_BUFF[0];
ifShiftValue = CAT_BUFF[1] + CAT_BUFF[2] * 256;
setFrequency(frequency);
SetCarrierFreq();
updateLine2Buffer(1); //option, perhap not need
Serial.write(ACK);
}
//void CatRxStatus(byte fromType)
void CatRxStatus(void) //for remove warning
{
@@ -768,6 +808,14 @@ void Check_Cat(byte fromType)
WriteEEPRom_FT817(fromType);
break;
case 0xDD: //Read uBITX ADC Data
ReadADCValue(); //Call by uBITX Manager Program
break;
case 0xDE: //IF-Shift Control by CAT
SetIFSValue(); //
break;
case 0xE7 : //Read RX Status
CatRxStatus();
break;

19
ubitx_20/cw_autokey.ino
View File

@@ -36,7 +36,7 @@
//27 + 10 + 18 + 1(SPACE) = //56
const PROGMEM uint8_t cwAZTable[27] = {0b00100100 , 0b01001000 , 0b01001010 , 0b00111000 , 0b00010000, 0b01000010, 0b00111100, 0b01000000 , //A ~ H
0b00100000, 0b01000111 ,0b00111010, 0b01000100, 0b00101100, 0b00101000 , 0b00111110, 0b01000110, 0b01001101, 0b00110100, //I ~ R
0b00110000, 0b00011000, 0b00110010, 0b01000001, 0b00110110, 0b01001001, 0b01001011, 0b00111000}; //S ~ Z
0b00110000, 0b00011000, 0b00110010, 0b01000001, 0b00110110, 0b01001001, 0b01001011, 0b01001100}; //S ~ Z
PGM_P pCwAZTable = reinterpret_cast<PGM_P>(cwAZTable);
const PROGMEM uint8_t cw09Table[27] = {0b00011111, 0b00001111, 0b00000111, 0b00000011, 0b00000001, 0b00000000, 0b00010000, 0b00011000, 0b00011100, 0b00011110};
@@ -297,15 +297,16 @@ void controlAutoCW(){
displayScrolStep = 0;
}
printLineFromEEPRom(0, 2, cwStartIndex + displayScrolStep + CW_DATA_OFSTADJ, cwEndIndex + CW_DATA_OFSTADJ);
printLineFromEEPRom(0, 2, cwStartIndex + displayScrolStep + CW_DATA_OFSTADJ, cwEndIndex + CW_DATA_OFSTADJ, 0);
byte diplayAutoCWLine = 0;
if ((displayOption1 & 0x01) == 0x01)
diplayAutoCWLine = 1;
lcd.setCursor(0, diplayAutoCWLine);
lcd.write(byteToChar(selectedCWTextIndex));
lcd.write(':');
//byte diplayAutoCWLine = 0;
//if ((displayOption1 & 0x01) == 0x01)
// diplayAutoCWLine = 1;
Display_AutoKeyTextIndex(selectedCWTextIndex);
//lcd.setCursor(0, diplayAutoCWLine);
//lcd.write(byteToChar(selectedCWTextIndex));
//lcd.write(':');
isNeedScroll = (cwEndIndex - cwStartIndex) > 14 ? 1 : 0;
scrollDispayTime = millis() + scrollSpeed;
beforeCWTextIndex = selectedCWTextIndex;

174
ubitx_20/ubitx.h Normal file
View File

@@ -0,0 +1,174 @@
/*************************************************************************
header file for C++ by 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
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/>.
**************************************************************************/
#include <Arduino.h> //for Linux, On Linux it is case sensitive.
//==============================================================================
// Compile Option
//==============================================================================
//Depending on the type of LCD mounted on the uBITX, uncomment one of the options below.
//You must select only one.
#define UBITX_DISPLAY_LCD1602P //LCD mounted on unmodified uBITX
//#define UBITX_DISPLAY_LCD1602I //I2C type 16 x 02 LCD
//#define UBITX_DISPLAY_LCD1602I_DUAL
//#define UBITX_DISPLAY_LCD2004P //24 x 04 LCD (Parallel)
//#define UBITX_DISPLAY_LCD2004I //I2C type 24 x 04 LCD
#define I2C_LCD_MASTER_ADDRESS_DEFAULT 0x3F //0x27 //DEFAULT, if Set I2C Address by uBITX Manager, read from EEProm
#define I2C_LCD_SECOND_ADDRESS_DEFAULT 0x27 //0x27 //only using Dual LCD Mode
#define EXTEND_KEY_GROUP1 //MODE, BAND(-), BAND(+), STEP
//#define EXTEND_KEY_GROUP2 //Numeric (0~9), Point(.), Enter //Not supported in Version 1.0x
#define ENABLE_FACTORYALIGN
//#define ENABLE_ADCMONITOR //Starting with Version 1.07, you can read ADC values directly from uBITX Manager. So this function is not necessary.
extern byte I2C_LCD_MASTER_ADDRESS; //0x27 //if Set I2C Address by uBITX Manager, read from EEProm
extern byte I2C_LCD_SECOND_ADDRESS; //only using Dual LCD Mode
#define SMeterLatency 3 //1 is 0.25 sec
#ifdef UBITX_DISPLAY_LCD1602I
#define USE_I2C_LCD
#elif defined(UBITX_DISPLAY_LCD1602I_DUAL)
#define USE_I2C_LCD
#elif defined(UBITX_DISPLAY_LCD2004I)
#define USE_I2C_LCD
#endif
//==============================================================================
// Hardware, Define PIN Usage
//==============================================================================
/**
* 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 5v 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), +5v
* 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 100K or 10K linear potentiometer with the two other ends connected to
* ground and +5v 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)
#define ANALOG_SMETER (A7) //by KD8CEC
/**
* 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 +5V 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) //Relay
#define CW_TONE (6)
#define TX_LPF_A (5) //Relay
#define TX_LPF_B (4) //Relay
#define TX_LPF_C (3) //Relay
#define CW_KEY (2)
//==============================================================================
// for public, Variable, functions
//==============================================================================
#define WSPR_BAND_COUNT 3
#define TX_SSB 0
#define TX_CW 1
#define printLineF1(x) (printLineF(1, x))
#define printLineF2(x) (printLineF(0, x))
//0x00 : None, 0x01 : MODE, 0x02:BAND+, 0x03:BAND-, 0x04:TUNE_STEP, 0x05:VFO Toggle, 0x06:SplitOn/Off, 0x07:TX/ON-OFF, 0x08:SDR Mode On / Off, 0x09:Rit Toggle
#define FUNCTION_KEY_ADC 80 //MODE, BAND(-), BAND(+), STEP
#define FKEY_PRESS 0x78
#define FKEY_MODE 0x01
#define FKEY_BANDUP 0x02
#define FKEY_BANDDOWN 0x03
#define FKEY_STEP 0x04
#define FKEY_VFOCHANGE 0x05
#define FKEY_SPLIT 0x06
#define FKEY_TXOFF 0x07
#define FKEY_SDRMODE 0x08
#define FKEY_RIT 0x09
#define FKEY_ENTER 0x0A
#define FKEY_POINT 0x0B
#define FKEY_DELETE 0x0C
#define FKEY_CANCEL 0x0D
#define FKEY_NUM0 0x10
#define FKEY_NUM1 0x11
#define FKEY_NUM2 0x12
#define FKEY_NUM3 0x13
#define FKEY_NUM4 0x14
#define FKEY_NUM5 0x15
#define FKEY_NUM6 0x16
#define FKEY_NUM7 0x17
#define FKEY_NUM8 0x18
#define FKEY_NUM9 0x19
#define FKEY_TYPE_MAX 0x1F
extern unsigned long frequency;
extern byte WsprMSGCount;
extern byte sMeterLevels[9];
extern byte KeyValues[16][3]; //Set : Start Value, End Value, Key Type, 16 Set (3 * 16 = 48)
extern void printLine1(const char *c);
extern void printLine2(const char *c);
extern void printLineF(char linenmbr, const __FlashStringHelper *c);
extern void printLineFromEEPRom(char linenmbr, char lcdColumn, byte eepromStartIndex, byte eepromEndIndex, char offsetType);
extern byte delay_background(unsigned delayTime, byte fromType);
extern int btnDown(void);
extern char c[30];
extern char b[30];
extern int enc_read(void);
extern void si5351bx_init(void);
extern void si5351bx_setfreq(uint8_t clknum, uint32_t fout);
extern void si5351_set_calibration(int32_t cal);
extern void initOscillators(void);
extern void Set_WSPR_Param(void);
extern void TXSubFreq(unsigned long P2);
extern void startTx(byte txMode, byte isDisplayUpdate);
extern void stopTx(void);
extern void setTXFilters(unsigned long freq);
extern void SendWSPRManage(void);
extern char byteToChar(byte srcByte);
extern void DisplayCallsign(byte callSignLength);
extern void DisplayVersionInfo(const char* fwVersionInfo);

625
ubitx_20/ubitx_20.ino
View File

@@ -1,8 +1,20 @@
//Firmware Version
//+ : This symbol identifies the firmware.
// It was originally called 'CEC V1.072' but it is too long to waste the LCD window.
// I do not want to make this Firmware users's uBITX messy with my callsign.
// Putting one alphabet in front of 'v' has a different meaning.
// So I put + in the sense that it was improved one by one based on Original Firmware.
// This firmware has been gradually changed based on the original firmware created by Farhan, Jack, Jerry and others.
#define FIRMWARE_VERSION_INFO F("+v1.073")
#define FIRMWARE_VERSION_NUM 0x02 //1st Complete Project : 1 (Version 1.061), 2st Project : 2
/**
Since KD8CEC Version 0.29, most of the original code is no longer available.
Cat Suppoort uBITX CEC Version
This firmware has been gradually changed based on the original firmware created by Farhan, Jack, Jerry and others.
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
My wish is to keep the original author's Comment as long as the meaning does not change much, even if the code looks a bit long.
Ian KD8CEC
Original source comment -------------------------------------------------------------
* This source file is under General Public License version 3.
@@ -38,167 +50,9 @@
*/
#include <Wire.h>
#include <EEPROM.h>
#include "ubitx.h"
#include "ubitx_eemap.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 5v 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), +5v
* 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 100K or 10K linear potentiometer with the two other ends connected to
* ground and +5v 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)
#define ANALOG_SMETER (A7) //by KD8CEC
/**
* The Raduino board is the size of a standard 16x2 LCD panel. It has three connectors:
*
* First, is an 8 pin connector that provides +5v, 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 16x2
* 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);
#define VERSION_NUM 0x01 //for KD8CEC'S firmware and for memory management software
/**
* 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 +5V 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
//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
#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
/**
* 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,
@@ -230,11 +84,6 @@ int count = 0; //to generally count ticks, loops, etc
#define LOWEST_FREQ_DIAL (3000l)
#define HIGHEST_FREQ_DIAL (60000000l)
//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
@@ -268,6 +117,7 @@ byte isTxType = 0; //000000[0 - isSplit] [0 - isTXStop]
long arTuneStep[5];
byte tuneStepIndex; //default Value 0, start Offset is 0 because of check new user
byte commonOption0 = 0;
byte displayOption1 = 0;
byte displayOption2 = 0;
@@ -285,6 +135,9 @@ bool Iambic_Key = true;
#define IAMBICB 0x10 // 0 for Iambic A, 1 for Iambic B
unsigned char keyerControl = IAMBICB;
byte isShiftDisplayCWFreq = 1; //Display Frequency
int shiftDisplayAdjustVal = 0; //
//Variables for auto cw mode
byte isCWAutoMode = 0; //0 : none, 1 : CW_AutoMode_Menu_Selection, 2 : CW_AutoMode Sending
byte cwAutoTextCount = 0; //cwAutoText Count
@@ -317,13 +170,25 @@ 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
byte advancedFreqOption1; //255 : Bit0: use IFTune_Value, Bit1 : use Stored enabled SDR Mode, Bit2~Bit3 : dynamic sdr frequency, bit 7: IFTune_Value Reverse for DIY uBITX
byte attLevel = 0; //ATT : RF Gain Control (Receive) <-- IF1 Shift, 0 : Off, ShiftValue is attLevel * 100; attLevel 150 = 15K
byte if1TuneValue = 0; //0 : OFF, IF1 + if1TuneValue * 100; // + - 12500;
byte sdrModeOn = 0; //SDR MODE ON / OFF
unsigned long SDR_Center_Freq; //
unsigned long beforeIdle_ProcessTime = 0; //for check Idle time
byte line2DisplayStatus = 0; //0:Clear, 1 : menu, 1: DisplayFrom Idle,
char lcdMeter[17];
byte sMeterLevels[9];
byte I2C_LCD_MASTER_ADDRESS; //0x27 //if Set I2C Address by uBITX Manager, read from EEProm
byte I2C_LCD_SECOND_ADDRESS; //only using Dual LCD Mode
byte KeyValues[16][3];
byte isIFShift = 0; //1 = ifShift, 2 extend
long ifShiftValue = 0; //
int ifShiftValue = 0; //
/**
* Below are the basic functions that control the uBitx. Understanding the functions before
@@ -332,8 +197,8 @@ long ifShiftValue = 0; //
//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))
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
@@ -401,7 +266,6 @@ void saveBandFreqByIndex(unsigned long f, unsigned long mode, char bandIndex) {
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();
@@ -485,29 +349,88 @@ void setTXFilters(unsigned long freq){
void setFrequency(unsigned long f){
f = (f / arTuneStep[tuneStepIndex -1]) * arTuneStep[tuneStepIndex -1];
setTXFilters(f);
if (cwMode == 0)
unsigned long appliedCarrier = ((cwMode == 0 ? usbCarrier : cwmCarrier) + (isIFShift && (inTx == 0) ? ifShiftValue : 0));
int appliedTuneValue = 0;
//applied if tune
//byte advancedFreqOption1; //255 : Bit0: use IFTune_Value, Bit1 : use Stored enabled SDR Mode, Bit2 : dynamic sdr frequency0, Bit3 : dynamic sdr frequency1, bit 7: IFTune_Value Reverse for DIY uBITX
if ((advancedFreqOption1 & 0x01) != 0x00)
{
if (isUSB){
si5351bx_setfreq(2, SECOND_OSC_USB - usbCarrier + f + (isIFShift ? ifShiftValue : 0));
si5351bx_setfreq(1, SECOND_OSC_USB);
appliedTuneValue = if1TuneValue;
//In the LSB state, the optimum reception value was found. To apply to USB, 3Khz decrease is required.
if (sdrModeOn && (inTx == 0))
appliedTuneValue -= 15; //decrease 1.55Khz
//if (isUSB)
if (cwMode == 2 || (cwMode == 0 && (isUSB)))
appliedTuneValue -= 30; //decrease 3Khz
}
//if1Tune RX, TX Enabled, ATT : only RX Mode
//The IF Tune shall be measured at the LSB. Then, move the 3Khz down for USB.
long if1AdjustValue = ((inTx == 0) ? (attLevel * 100) : 0) + (appliedTuneValue * 100); //if1Tune RX, TX Enabled, ATT : only RX Mode //5600
//for DIY uBITX (custom filter)
if ((advancedFreqOption1 & 0x80) != 0x00) //Reverse IF Tune (- Value for DIY uBITX)
if1AdjustValue *= -1;
if (sdrModeOn && (inTx == 0)) //IF SDR MODE
{
//Fixed Frequency SDR (Default Frequency : 32Mhz, available change sdr Frequency by uBITX Manager)
//Dynamic Frequency is for SWL without cat
//byte advancedFreqOption1; //255 : Bit0: use IFTune_Value, Bit1 : use Stored enabled SDR Mode, Bit2 : dynamic sdr frequency0, Bit3 : dynamic sdr frequency1, bit 7: IFTune_Value Reverse for DIY uBITX
long moveFrequency = 0;
//7 6 5 4 3 2 1 0
// _ _ <-- SDR Freuqncy Option
byte sdrOption = (advancedFreqOption1 >> 2) & 0x03;
if (sdrOption == 1) // SDR Frequency + frequenc
{
//example : offset Freq : 20 Mhz and frequency = 7.080 => 27.080 Mhz
//example : offset Freq : 0 Mhz and frequency = 7.080 => 7.080 Mhz
//for available HF, SDR
moveFrequency = f;
}
else{
si5351bx_setfreq(2, SECOND_OSC_LSB + usbCarrier + f + (isIFShift ? ifShiftValue : 0));
si5351bx_setfreq(1, SECOND_OSC_LSB);
else if (sdrOption == 2) //Mhz move
{
//Offset Frequency + Mhz,
//Example : Offset Frequency : 30Mhz and current Frequncy is 7.080 => 37.080Mhz
// Offset Frequency : 30Mhz and current Frequncy is 14.074 => 34.074Mhz
moveFrequency = (f % 10000000);
}
else if (sdrOption == 3) //Khz move
{
//Offset Frequency + Khz,
//Example : Offset Frequency : 30Mhz and current Frequncy is 7.080 => 30.080Mhz
// Offset Frequency : 30Mhz and current Frequncy is 14.074 => 30.074Mhz
moveFrequency = (f % 1000000);
}
si5351bx_setfreq(2, 44991500 + if1AdjustValue + f);
si5351bx_setfreq(1, 44991500
+ if1AdjustValue
+ SDR_Center_Freq
//+ ((advancedFreqOption1 & 0x04) == 0x00 ? 0 : (f % 10000000))
+ moveFrequency
+ 2390);
}
else
{
if (cwMode == 1){ //CWL
si5351bx_setfreq(2, SECOND_OSC_LSB + cwmCarrier + f + (isIFShift ? ifShiftValue : 0));
si5351bx_setfreq(1, SECOND_OSC_LSB);
if (cwMode == 1 || (cwMode == 0 && (!isUSB))) //cwl or lsb
{
//CWL(cwMode == 1) or LSB (cwMode == 0 && (!isUSB))
si5351bx_setfreq(2, SECOND_OSC_LSB + if1AdjustValue + appliedCarrier + f);
si5351bx_setfreq(1, SECOND_OSC_LSB + if1AdjustValue);
}
else{ //CWU
si5351bx_setfreq(2, SECOND_OSC_USB - cwmCarrier + f + (isIFShift ? ifShiftValue : 0));
si5351bx_setfreq(1, SECOND_OSC_USB);
else //cwu or usb
{
//CWU (cwMode == 2) or USB (cwMode == 0 and isUSB)
si5351bx_setfreq(2, SECOND_OSC_USB + if1AdjustValue - appliedCarrier + f);
si5351bx_setfreq(1, SECOND_OSC_USB + if1AdjustValue);
}
}
@@ -519,7 +442,6 @@ void setFrequency(unsigned long f){
* 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
*/
void startTx(byte txMode, byte isDisplayUpdate){
//Check Hamband only TX //Not found Hamband index by now frequency
if (tuneTXType >= 100 && getIndexHambanBbyFreq(ritOn ? ritTxFrequency : frequency) == -1) {
@@ -537,7 +459,9 @@ void startTx(byte txMode, byte isDisplayUpdate){
ritRxFrequency = frequency;
setFrequency(ritTxFrequency);
}
else if (splitOn == 1) {
else
{
if (splitOn == 1) {
if (vfoActive == VFO_B) {
vfoActive = VFO_A;
frequency = vfoA;
@@ -548,10 +472,12 @@ void startTx(byte txMode, byte isDisplayUpdate){
frequency = vfoB;
byteToMode(vfoB_mode, 0);
}
}
setFrequency(frequency);
setFrequency(frequency);
} //end of else
SetCarrierFreq();
if (txMode == TX_CW){
//turn off the second local oscillator and the bfo
@@ -584,19 +510,17 @@ void startTx(byte txMode, byte isDisplayUpdate){
updateDisplay();
}
void stopTx(){
void stopTx(void){
inTx = 0;
digitalWrite(TX_RX, 0); //turn off the tx
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
SetCarrierFreq();
if (ritOn)
setFrequency(ritRxFrequency);
else if (splitOn == 1) {
else
{
if (splitOn == 1) {
//vfo Change
if (vfoActive == VFO_B){
vfoActive = VFO_A;
@@ -608,10 +532,10 @@ void stopTx(){
frequency = vfoB;
byteToMode(vfoB_mode, 0);
}
setFrequency(frequency);
} //end of else
else
}
setFrequency(frequency);
} //end of else
updateDisplay();
}
@@ -646,7 +570,7 @@ void ritDisable(){
* flip the T/R line to T and update the display to denote transmission
*/
void checkPTT(){
void checkPTT(){
//we don't check for ptt when transmitting cw
if (cwTimeout > 0)
return;
@@ -655,11 +579,172 @@ void checkPTT(){
startTx(TX_SSB, 1);
delay(50); //debounce the PTT
}
if (digitalRead(PTT) == 1 && inTx == 1)
stopTx();
}
#ifdef EXTEND_KEY_GROUP1
void checkButton(){
char currentBandIndex = -1;
//only if the button is pressed
int keyStatus = getBtnStatus();
if (keyStatus == -1)
return;
delay(50);
keyStatus = getBtnStatus(); //will be remove 3 lines
if (keyStatus == -1)
return;
if (keyStatus == FKEY_PRESS) //Menu Key
doMenu();
else if (keyStatus <= FKEY_TYPE_MAX) //EXTEND KEY GROUP #1
{
switch(keyStatus)
{
case FKEY_MODE :
if (cwMode == 1)
{
cwMode = 2;
}
else if (cwMode == 2)
{
cwMode = 0;
isUSB = 0;
}
else if (isUSB == 0)
{
isUSB = 1;
}
else
{
cwMode = 1;
}
break;
case FKEY_BANDUP :
case FKEY_BANDDOWN :
//Save Band Information
if (tuneTXType == 2 || tuneTXType == 3 || tuneTXType == 102 || tuneTXType == 103) { //only ham band move
currentBandIndex = getIndexHambanBbyFreq(frequency);
if (currentBandIndex >= 0) {
saveBandFreqByIndex(frequency, modeToByte(), currentBandIndex);
}
}
setNextHamBandFreq(frequency, keyStatus == FKEY_BANDDOWN ? -1 : 1); //Prior Band
break;
case FKEY_STEP :
if (++tuneStepIndex > 5)
tuneStepIndex = 1;
EEPROM.put(TUNING_STEP, tuneStepIndex);
printLine2ClearAndUpdate();
break;
case FKEY_VFOCHANGE :
menuVfoToggle(1); //Vfo Toggle
break;
case FKEY_SPLIT :
menuSplitOnOff(1);
break;
case FKEY_TXOFF:
menuTxOnOff(1, 0x01);
break;
case FKEY_SDRMODE :
menuSDROnOff(1);
break;
case FKEY_RIT :
menuRitToggle(1);
break;
}
/*
if (keyStatus == FKEY_MODE) //Press Mode Key
{
if (cwMode == 1)
{
cwMode = 2;
}
else if (cwMode == 2)
{
cwMode = 0;
isUSB = 0;
}
else if (isUSB == 0)
{
isUSB = 1;
}
else
{
cwMode = 1;
}
}
else if (keyStatus == FKEY_BANDUP || keyStatus == FKEY_BANDDOWN) //Press Mode Key
{
char currentBandIndex = -1;
//Save Band Information
if (tuneTXType == 2 || tuneTXType == 3 || tuneTXType == 102 || tuneTXType == 103) { //only ham band move
currentBandIndex = getIndexHambanBbyFreq(frequency);
if (currentBandIndex >= 0) {
saveBandFreqByIndex(frequency, modeToByte(), currentBandIndex);
}
}
setNextHamBandFreq(frequency, keyStatus == FKEY_BANDDOWN ? -1 : 1); //Prior Band
}
else if (keyStatus == FKEY_STEP) //FKEY_BANDUP
{
if (++tuneStepIndex > 5)
tuneStepIndex = 1;
EEPROM.put(TUNING_STEP, tuneStepIndex);
printLine2ClearAndUpdate();
}
else if (keyStatus == FKEY_VFOCHANGE)
{
menuVfoToggle(1); //Vfo Toggle
}
else if (keyStatus == FKEY_SPLIT)
{
menuSplitOnOff(1);
}
else if (keyStatus == FKEY_TXOFF)
{
menuTxOnOff(1, 0x01);
}
else if (keyStatus == FKEY_SDRMODE)
{
menuSDROnOff(1);
}
else if (keyStatus == FKEY_RIT)
{
menuRitToggle(1);
}
*/
FrequencyToVFO(1);
SetCarrierFreq();
setFrequency(frequency);
//delay_background(delayTime, 0);
updateDisplay();
}
//wait for the button to go up again
while(keyStatus == getBtnStatus()) {
delay(10);
Check_Cat(0);
}
//delay(50);//debounce
}
#else
void checkButton(){
//only if the button is pressed
if (!btnDown())
@@ -675,9 +760,9 @@ void checkButton(){
delay(10);
Check_Cat(0);
}
delay(50);//debounce
//delay(50);//debounce
}
#endif
/************************************
Replace function by KD8CEC
@@ -690,7 +775,7 @@ 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
//#define skipThresholdTime 70
#define encodeTimeOut 1000
void doTuningWithThresHold(){
@@ -701,8 +786,7 @@ void doTuningWithThresHold(){
(vfoActive == VFO_B && ((isDialLock & 0x02) == 0x02)))
return;
if (isCWAutoMode == 0 || cwAutoDialType == 1)
s = enc_read();
s = enc_read();
//if time is exceeded, it is recognized as an error,
//ignore exists values, because of errors
@@ -719,7 +803,9 @@ void doTuningWithThresHold(){
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)))
//not use continues changing by Threshold
//if ((lastTunetime < (millis() - skipThresholdTime)) && ((encodedSumValue * encodedSumValue) <= (threshold * threshold)))
if (((encodedSumValue * encodedSumValue) <= (threshold * threshold)))
return;
lastTunetime = millis();
@@ -729,7 +815,8 @@ void doTuningWithThresHold(){
prev_freq = frequency;
//incdecValue = tuningStep * s;
frequency += (arTuneStep[tuneStepIndex -1] * s * (s * s < 10 ? 1 : 3)); //appield weight (s is speed)
//frequency += (arTuneStep[tuneStepIndex -1] * s * (s * s < 10 ? 1 : 3)); //appield weight (s is speed)
frequency += (arTuneStep[tuneStepIndex -1] * s); //appield weight (s is speed) //if want need more increase size, change step size
if (prev_freq < 10000000l && frequency > 10000000l)
isUSB = true;
@@ -750,16 +837,15 @@ void doRIT(){
if (knob < 0)
frequency -= (arTuneStep[tuneStepIndex -1]); //
//frequency -= 100l;
else if (knob > 0)
frequency += (arTuneStep[tuneStepIndex -1]); //
//frequency += 100;
if (old_freq != frequency){
setFrequency(frequency);
updateDisplay();
}
}
/*
save Frequency and mode to eeprom for Auto Save with protected eeprom cycle, by kd8cec
*/
@@ -838,7 +924,7 @@ void initSettings(){
printLineF(1, F("Init EEProm..."));
//initial all eeprom
for (unsigned int i = 32; i < 1024; i++) //protect Master_cal, usb_cal
for (unsigned int i = 64; i < 1024; i++) //protect Master_cal, usb_cal
EEPROM.write(i, 0);
//Write Firmware ID
@@ -848,8 +934,8 @@ void initSettings(){
}
//Version Write for Memory Management Software
if (EEPROM.read(VERSION_ADDRESS) != VERSION_NUM)
EEPROM.write(VERSION_ADDRESS, VERSION_NUM);
if (EEPROM.read(VERSION_ADDRESS) != FIRMWARE_VERSION_NUM)
EEPROM.write(VERSION_ADDRESS, FIRMWARE_VERSION_NUM);
EEPROM.get(CW_CAL, cwmCarrier);
@@ -877,11 +963,22 @@ void initSettings(){
else
keyerControl |= IAMBICB;
}
EEPROM.get(COMMON_OPTION0, commonOption0);
EEPROM.get(DISPLAY_OPTION1, displayOption1);
EEPROM.get(DISPLAY_OPTION2, displayOption2);
for (byte i = 0; i < 8; i++) {
sMeterLevels[i + 1] = EEPROM.read(S_METER_LEVELS + i);
}
//KeyValues
for (byte i = 0; i < 16; i++) {
KeyValues[i][0] = EEPROM.read(EXTENDED_KEY_RANGE + (i * 3)); //RANGE : Start Value
KeyValues[i][1] = EEPROM.read(EXTENDED_KEY_RANGE + (i * 3) + 1); //RANGE : End Value
KeyValues[i][2] = EEPROM.read(EXTENDED_KEY_RANGE + (i * 3) + 2); //KEY TYPE
}
//User callsign information
if (EEPROM.read(USER_CALLSIGN_KEY) == 0x59)
userCallsignLength = EEPROM.read(USER_CALLSIGN_LEN); //MAXIMUM 18 LENGTH
@@ -939,10 +1036,10 @@ void initSettings(){
{
//Default Setting
arTuneStep[0] = 10;
arTuneStep[1] = 20;
arTuneStep[2] = 50;
arTuneStep[3] = 100;
arTuneStep[4] = 200;
arTuneStep[1] = 50;
arTuneStep[2] = 100;
arTuneStep[3] = 500;
arTuneStep[4] = 1000;
}
if (tuneStepIndex == 0) //New User
@@ -963,6 +1060,52 @@ void initSettings(){
cwAdcBothFrom = EEPROM.read(CW_ADC_BOTH_FROM) | ((tmpMostBits & 0x30) << 4);
cwAdcBothTo = EEPROM.read(CW_ADC_BOTH_TO) | ((tmpMostBits & 0xC0) << 2);
//Display Type for CW mode
isShiftDisplayCWFreq = EEPROM.read(CW_DISPLAY_SHIFT);
//Enable / Diable Check for CW Display Cofiguration Group
if ((commonOption0 & 0x80) != 0x00)
{
//Adjust CW Mode Freq
shiftDisplayAdjustVal = (isShiftDisplayCWFreq & 0x3F) * 10;
//check Minus
if ((isShiftDisplayCWFreq & 0x40) == 0x40)
shiftDisplayAdjustVal = shiftDisplayAdjustVal * -1;
//Shift Display Check (Default : 0)
if ((isShiftDisplayCWFreq & 0x80) == 0) //Enabled
isShiftDisplayCWFreq = 1;
else //Disabled
isShiftDisplayCWFreq = 0;
}
//Stored IF Shift Option
if ((commonOption0 & 0x40) != 0x00)
{
EEPROM.get(IF_SHIFTVALUE, ifShiftValue);
isIFShift = ifShiftValue != 0;
}
//Advanced Freq control
EEPROM.get(ADVANCED_FREQ_OPTION1, advancedFreqOption1);
//byte advancedFreqOption1; //255 : Bit0: use IFTune_Value, Bit1 : use Stored enabled SDR Mode, Bit2 : dynamic sdr frequency0, Bit3 : dynamic sdr frequency1, bit 7: IFTune_Value Reverse for DIY uBITX
if ((advancedFreqOption1 & 0x01) != 0x00)
{
EEPROM.get(IF1_CAL, if1TuneValue);
//Stored Enabled SDR Mode
if ((advancedFreqOption1 & 0x02) != 0x00)
{
EEPROM.get(ENABLE_SDR, sdrModeOn);
}
}
EEPROM.get(SDR_FREQUNCY, SDR_Center_Freq);
//if (SDR_Center_Freq == 0)
// SDR_Center_Freq = 32000000;
//default Value (for original hardware)
if (cwAdcSTFrom >= cwAdcSTTo)
{
@@ -999,10 +1142,10 @@ void initSettings(){
//original code with modified by kd8cec
if (usbCarrier > 12010000l || usbCarrier < 11990000l)
usbCarrier = 11995000l;
usbCarrier = 11997000l;
if (cwmCarrier > 12010000l || cwmCarrier < 11990000l)
cwmCarrier = 11995000l;
cwmCarrier = 11997000l;
if (vfoA > 35000000l || 3500000l > vfoA) {
vfoA = 7150000l;
@@ -1037,7 +1180,6 @@ void initSettings(){
}
void initPorts(){
analogReference(DEFAULT);
//??
@@ -1084,19 +1226,33 @@ void setup()
//while(1);
//end section of test
*/
//Load I2C LCD Address for I2C LCD
//I2C LCD Parametere
#ifdef USE_I2C_LCD
EEPROM.get(I2C_LCD_MASTER, I2C_LCD_MASTER_ADDRESS);
EEPROM.get(I2C_LCD_SECOND, I2C_LCD_SECOND_ADDRESS);
if (I2C_LCD_MASTER_ADDRESS < 0x10 || I2C_LCD_MASTER_ADDRESS > 0xF0)
I2C_LCD_MASTER_ADDRESS = I2C_LCD_MASTER_ADDRESS_DEFAULT;
if (I2C_LCD_SECOND_ADDRESS < 0x10 || I2C_LCD_SECOND_ADDRESS > 0xF0)
I2C_LCD_SECOND_ADDRESS = I2C_LCD_SECOND_ADDRESS_DEFAULT;
#endif
//Serial.begin(9600);
lcd.begin(16, 2);
printLineF(1, F("CECBT v1.01"));
LCD_Init();
//printLineF(1, FIRMWARE_VERSION_INFO);
DisplayVersionInfo(FIRMWARE_VERSION_INFO);
Init_Cat(38400, SERIAL_8N1);
initMeter(); //not used in this build
initSettings();
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);
//printLineFromEEPRom(0, 0, 0, userCallsignLength -1, 0); //eeprom to lcd use offset (USER_CALLSIGN_DAT)
//delay(500);
DisplayCallsign(userCallsignLength);
}
else {
printLineF(0, F("uBITX v0.20"));
@@ -1114,8 +1270,10 @@ void setup()
setFrequency(vfoA);
updateDisplay();
#ifdef ENABLE_FACTORYALIGN
if (btnDown())
factory_alignment();
#endif
}
//Auto save Frequency and Mode with Protected eeprom life by KD8CEC
@@ -1155,12 +1313,13 @@ void loop(){
//tune only when not tranmsitting
if (!inTx){
if (ritOn)
doRIT();
//else if (isIFShift)
// doIFShift();
else
doTuningWithThresHold();
if (isCWAutoMode == 0 || cwAutoDialType == 1)
{
if (ritOn)
doRIT();
else
doTuningWithThresHold();
}
if (isCWAutoMode == 0 && beforeIdle_ProcessTime < millis() - 250) {
idle_process();

127
ubitx_20/ubitx_eemap.h Normal file
View File

@@ -0,0 +1,127 @@
/*************************************************************************
header file for EEProm Address Map by KD8CEC
It must be protected to protect the factory calibrated calibration.
-----------------------------------------------------------------------------
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/>.
**************************************************************************/
//==============================================================================
// Factory-shipped EEProm address
// (factory Firmware)
// Address : 0 ~ 31
//==============================================================================
#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
//==============================================================================
// The spare space available in the original firmware #1
// Address : 32 ~ 63
//==============================================================================
#define RESERVE_FOR_FACTORY1 32
//==============================================================================
// The spare space available in the original firmware #2
// (Enabled if the EEProm address is insufficient)
// Address : 64 ~ 100
//==============================================================================
#define RESERVE_FOR_FACTORY2 64
//==============================================================================
// KD8CEC EEPROM MAP
// Address : 101 ~ 1023
// 256 is the base address
// 256 ~ 1023 (EEProm Section #1)
// 255 ~ 101 (EEProm Section #2)
//==============================================================================
//0x00 : None, 0x01 : MODE, 0x02:BAND+, 0x03:BAND-, 0x04:TUNE_STEP, 0x05:VFO Toggle, 0x06:SplitOn/Off, 0x07:TX/ON-OFF, 0x08:SDR Mode On / Off, 0x09:Rit Toggle
#define EXTENDED_KEY_RANGE 140 //Extended Key => Set : Start Value, End Value, Key Type, 16 Set (3 * 16 = 48)
#define I2C_LCD_MASTER 190
#define I2C_LCD_SECOND 191
#define S_METER_LEVELS 230 //LEVEL0 ~ LEVEL7
#define ADVANCED_FREQ_OPTION1 240 //Bit0: use IFTune_Value, Bit1 : use Stored enabled SDR Mode, Bit2 : dynamic sdr frequency
#define IF1_CAL 241
#define ENABLE_SDR 242
#define SDR_FREQUNCY 243
#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 CW_DISPLAY_SHIFT 359 //Transmits on CWL, CWU Mode, LCD Frequency shifts Sidetone Frequency.
//(7:Enable / Disable //0: enable, 1:disable, (default is applied shift)
//6 : 0 : Adjust Pulus, 1 : Adjust Minus
//0~5: Adjust Value : * 10 = Adjust Value (0~300)
#define COMMON_OPTION0 360 //0: Confirm : CW Frequency Shift
//1 : IF Shift Save
#define IF_SHIFTVALUE 363
#define DISPLAY_OPTION1 361 //Display Option1
#define DISPLAY_OPTION2 362 //Display Option2
#define WSPR_COUNT 443 //WSPR_MESSAGE_COUNT
#define WSPR_MESSAGE1 444 //
#define WSPR_MESSAGE2 490 //
#define WSPR_MESSAGE3 536 //
#define WSPR_MESSAGE4 582 //
#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
#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

259
ubitx_20/ubitx_idle.ino
View File

@@ -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;
*/
}
}
}

15
ubitx_20/ubitx_keyer.ino
View File

@@ -168,6 +168,8 @@ void cwKeyer(void){
break;
case KEYED_PREP:
//modified KD8CEC
/*
ktimer += millis(); // set ktimer to interval end time
keyerControl &= ~(DIT_L + DAH_L); // clear both paddle latch bits
keyerState = KEYED; // next state
@@ -179,6 +181,19 @@ void cwKeyer(void){
cwTimeout = millis() + cwDelayTime * 10; //+ CW_TIMEOUT;
startTx(TX_CW, 1);
}
*/
if (!inTx){
//DelayTime Option
delay_background(delayBeforeCWStartTime * 2, 2);
keyDown = 0;
cwTimeout = millis() + cwDelayTime * 10; //+ CW_TIMEOUT;
startTx(TX_CW, 1);
}
ktimer += millis(); // set ktimer to interval end time
keyerControl &= ~(DIT_L + DAH_L); // clear both paddle latch bits
keyerState = KEYED; // next state
cwKeydown();
break;

840
ubitx_20/ubitx_lcd_1602.ino Normal file
View File

@@ -0,0 +1,840 @@
/*************************************************************************
KD8CEC's uBITX Display Routine for LCD1602 Parrel
1.This is the display code for the default LCD mounted in uBITX.
2.Display related functions of uBITX. Some functions moved from uBITX_Ui.
3.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/>.
**************************************************************************/
#include "ubitx.h"
//Common Defines *********************************************************
#define LCD_CLEARDISPLAY 0x01
#define LCD_RETURNHOME 0x02
#define LCD_ENTRYMODESET 0x04
#define LCD_DISPLAYCONTROL 0x08
#define LCD_CURSORSHIFT 0x10
#define LCD_FUNCTIONSET 0x20
#define LCD_SETCGRAMADDR 0x40
#define LCD_SETDDRAMADDR 0x80
// flags for display entry mode
#define LCD_ENTRYRIGHT 0x00
#define LCD_ENTRYLEFT 0x02
#define LCD_ENTRYSHIFTINCREMENT 0x01
#define LCD_ENTRYSHIFTDECREMENT 0x00
// flags for display on/off control
#define LCD_DISPLAYON 0x04
#define LCD_DISPLAYOFF 0x00
#define LCD_CURSORON 0x02
#define LCD_CURSOROFF 0x00
#define LCD_BLINKON 0x01
#define LCD_BLINKOFF 0x00
// flags for display/cursor shift
#define LCD_DISPLAYMOVE 0x08
#define LCD_CURSORMOVE 0x00
#define LCD_MOVERIGHT 0x04
#define LCD_MOVELEFT 0x00
// flags for function set
#define LCD_8BITMODE 0x10
#define LCD_4BITMODE 0x00
#define LCD_2LINE 0x08
#define LCD_1LINE 0x00
#define LCD_5x10DOTS 0x04
#define LCD_5x8DOTS 0x00
// flags for backlight control
#define LCD_BACKLIGHT 0x08
#define LCD_NOBACKLIGHT 0x00
//========================================================================
//Begin of TinyLCD Library by KD8CEC
//========================================================================
#ifdef UBITX_DISPLAY_LCD1602P
/*************************************************************************
LCD1602_TINY Library for 16 x 2 LCD
Referecnce Source : LiquidCrystal.cpp
KD8CEC
This source code is modified version for small program memory
from Arduino LiquidCrystal Library
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
**************************************************************************/
#define LCD_Command(x) (LCD_Send(x, LOW))
#define LCD_Write(x) (LCD_Send(x, HIGH))
#define UBITX_DISPLAY_LCD1602_BASE
//Define connected PIN
#define LCD_PIN_RS 8
#define LCD_PIN_EN 9
uint8_t LCD_PIN_DAT[4] = {10, 11, 12, 13};
void write4bits(uint8_t value)
{
for (int i = 0; i < 4; i++)
digitalWrite(LCD_PIN_DAT[i], (value >> i) & 0x01);
digitalWrite(LCD_PIN_EN, LOW);
delayMicroseconds(1);
digitalWrite(LCD_PIN_EN, HIGH);
delayMicroseconds(1); // enable pulse must be >450ns
digitalWrite(LCD_PIN_EN, LOW);
delayMicroseconds(100); // commands need > 37us to settle
}
void LCD_Send(uint8_t value, uint8_t mode)
{
digitalWrite(LCD_PIN_RS, mode);
write4bits(value>>4);
write4bits(value);
}
void LCD1602_Init()
{
pinMode(LCD_PIN_RS, OUTPUT);
pinMode(LCD_PIN_EN, OUTPUT);
for (int i = 0; i < 4; i++)
pinMode(LCD_PIN_DAT[i], OUTPUT);
delayMicroseconds(50);
// Now we pull both RS and R/W low to begin commands
digitalWrite(LCD_PIN_RS, LOW);
digitalWrite(LCD_PIN_EN, LOW);
// we start in 8bit mode, try to set 4 bit mode
write4bits(0x03);
delayMicroseconds(4500); // wait min 4.1ms
// second try
write4bits(0x03);
delayMicroseconds(4500); // wait min 4.1ms
// third go!
write4bits(0x03);
delayMicroseconds(150);
// finally, set to 4-bit interface
write4bits(0x02);
// finally, set # lines, font size, etc.
LCD_Command(LCD_FUNCTIONSET | LCD_4BITMODE | LCD_1LINE | LCD_5x8DOTS | LCD_2LINE);
// turn the display on with no cursor or blinking default
LCD_Command(LCD_DISPLAYCONTROL | LCD_DISPLAYON | LCD_CURSOROFF | LCD_BLINKOFF);
// clear it off
LCD_Command(LCD_CLEARDISPLAY); // clear display, set cursor position to zero
delayMicroseconds(2000); // this command takes a long time!
LCD_Command(LCD_ENTRYMODESET | LCD_ENTRYLEFT | LCD_ENTRYSHIFTDECREMENT);
}
#endif
//========================================================================
//End of TinyLCD Library by KD8CEC
//========================================================================
//========================================================================
//Begin of I2CTinyLCD Library by KD8CEC
//========================================================================
#ifdef UBITX_DISPLAY_LCD1602I
#include <Wire.h>
/*************************************************************************
I2C Tiny LCD Library
Referecnce Source : LiquidCrystal_I2C.cpp // Based on the work by DFRobot
KD8CEC
This source code is modified version for small program memory
from Arduino LiquidCrystal_I2C Library
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.
Ian KD8CEC
**************************************************************************/
#define UBITX_DISPLAY_LCD1602_BASE
#define En B00000100 // Enable bit
#define Rw B00000010 // Read/Write bit
#define Rs B00000001 // Register select bit
#define LCD_Command(x) (LCD_Send(x, 0))
#define LCD_Write(x) (LCD_Send(x, Rs))
uint8_t _Addr;
uint8_t _displayfunction;
uint8_t _displaycontrol;
uint8_t _displaymode;
uint8_t _numlines;
uint8_t _cols;
uint8_t _rows;
uint8_t _backlightval;
#define printIIC(args) Wire.write(args)
void expanderWrite(uint8_t _data)
{
Wire.beginTransmission(_Addr);
printIIC((int)(_data) | _backlightval);
Wire.endTransmission();
}
void pulseEnable(uint8_t _data){
expanderWrite(_data | En); // En high
delayMicroseconds(1); // enable pulse must be >450ns
expanderWrite(_data & ~En); // En low
delayMicroseconds(50); // commands need > 37us to settle
}
void write4bits(uint8_t value)
{
expanderWrite(value);
pulseEnable(value);
}
void LCD_Send(uint8_t value, uint8_t mode)
{
uint8_t highnib=value&0xf0;
uint8_t lownib=(value<<4)&0xf0;
write4bits((highnib)|mode);
write4bits((lownib)|mode);
}
// Turn the (optional) backlight off/on
void noBacklight(void) {
_backlightval=LCD_NOBACKLIGHT;
expanderWrite(0);
}
void backlight(void) {
_backlightval=LCD_BACKLIGHT;
expanderWrite(0);
}
void LCD1602_Init()
{
//I2C Init
_Addr = I2C_LCD_MASTER_ADDRESS;
_cols = 16;
_rows = 2;
_backlightval = LCD_NOBACKLIGHT;
Wire.begin();
delay(50);
// Now we pull both RS and R/W low to begin commands
expanderWrite(_backlightval); // reset expanderand turn backlight off (Bit 8 =1)
delay(1000);
//put the LCD into 4 bit mode
// this is according to the hitachi HD44780 datasheet
// figure 24, pg 46
// we start in 8bit mode, try to set 4 bit mode
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// second try
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// third go!
write4bits(0x03 << 4);
delayMicroseconds(150);
// finally, set to 4-bit interface
write4bits(0x02 << 4);
// finally, set # lines, font size, etc.
LCD_Command(LCD_FUNCTIONSET | LCD_4BITMODE | LCD_1LINE | LCD_5x8DOTS | LCD_2LINE);
// turn the display on with no cursor or blinking default
LCD_Command(LCD_DISPLAYCONTROL | LCD_DISPLAYON | LCD_CURSOROFF | LCD_BLINKOFF);
// clear it off
LCD_Command(LCD_CLEARDISPLAY); // clear display, set cursor position to zero
//delayMicroseconds(2000); // this command takes a long time!
delayMicroseconds(1000); // this command takes a long time!
LCD_Command(LCD_ENTRYMODESET | LCD_ENTRYLEFT | LCD_ENTRYSHIFTDECREMENT);
backlight();
}
/*
void LCD_Print(const char *c)
{
for (uint8_t i = 0; i < strlen(c); i++)
{
if (*(c + i) == 0x00) return;
LCD_Write(*(c + i));
}
}
void LCD_SetCursor(uint8_t col, uint8_t row)
{
LCD_Command(LCD_SETDDRAMADDR | (col + row * 0x40)); //0 : 0x00, 1 : 0x40, only for 16 x 2 lcd
}
void LCD_CreateChar(uint8_t location, uint8_t charmap[])
{
location &= 0x7; // we only have 8 locations 0-7
LCD_Command(LCD_SETCGRAMADDR | (location << 3));
for (int i=0; i<8; i++)
LCD_Write(charmap[i]);
}
*/
#endif
//========================================================================
//End of I2CTinyLCD Library by KD8CEC
//========================================================================
//========================================================================
// 16 X 02 LCD Routines
//Begin of Display Base Routines (Init, printLine..)
//========================================================================
#ifdef UBITX_DISPLAY_LCD1602_BASE
//SWR GRAPH, DrawMeter and drawingMeter Logic function by VK2ETA
#define OPTION_SKINNYBARS
char c[30], b[30];
char printBuff[2][17]; //mirrors what is showing on the two lines of the display
void LCD_Print(const char *c)
{
for (uint8_t i = 0; i < strlen(c); i++)
{
if (*(c + i) == 0x00) return;
LCD_Write(*(c + i));
}
}
void LCD_SetCursor(uint8_t col, uint8_t row)
{
LCD_Command(LCD_SETDDRAMADDR | (col + row * 0x40)); //0 : 0x00, 1 : 0x40, only for 16 x 2 lcd
}
void LCD_CreateChar(uint8_t location, uint8_t charmap[])
{
location &= 0x7; // we only have 8 locations 0-7
LCD_Command(LCD_SETCGRAMADDR | (location << 3));
for (int i=0; i<8; i++)
LCD_Write(charmap[i]);
}
void LCD_Init(void)
{
LCD1602_Init();
initMeter(); //for Meter Display
}
// 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
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);
strcpy(printBuff[linenmbr], c);
for (byte i = strlen(c); i < 16; i++) { // add white spaces until the end of the 16 characters line is reached
LCD_Write(' ');
}
}
}
void printLineF(char linenmbr, const __FlashStringHelper *c)
{
int i;
char tmpBuff[17];
PGM_P p = reinterpret_cast<PGM_P>(c);
for (i = 0; i < 17; i++){
unsigned char fChar = pgm_read_byte(p++);
tmpBuff[i] = fChar;
if (fChar == 0)
break;
}
printLine(linenmbr, tmpBuff);
}
#define LCD_MAX_COLUMN 16
void printLineFromEEPRom(char linenmbr, char lcdColumn, byte eepromStartIndex, byte eepromEndIndex, char offsetTtype) {
if ((displayOption1 & 0x01) == 0x01)
linenmbr = (linenmbr == 0 ? 1 : 0); //Line Toggle
LCD_SetCursor(lcdColumn, linenmbr);
for (byte i = eepromStartIndex; i <= eepromEndIndex; i++)
{
if (++lcdColumn <= LCD_MAX_COLUMN)
LCD_Write(EEPROM.read((offsetTtype == 0 ? USER_CALLSIGN_DAT : WSPR_MESSAGE1) + i));
else
break;
}
for (byte i = lcdColumn; i < 16; i++) //Right Padding by Space
LCD_Write(' ');
}
// short cut to print to the first line
void printLine1(const char *c)
{
printLine(1,c);
}
// short cut to print to the first line
void printLine2(const char *c)
{
printLine(0,c);
}
void clearLine2()
{
printLine2("");
line2DisplayStatus = 0;
}
// short cut to print to the first line
void printLine1Clear(){
printLine(1,"");
}
// short cut to print to the first line
void printLine2Clear(){
printLine(0, "");
}
void printLine2ClearAndUpdate(){
printLine(0, "");
line2DisplayStatus = 0;
updateDisplay();
}
//==================================================================================
//End of Display Base Routines
//==================================================================================
//==================================================================================
//Begin of User Interface Routines
//==================================================================================
//Main Display
// this builds up the top line of the display with frequency and mode
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; //
memset(c, 0, sizeof(c));
if (inTx){
if (isCWAutoMode == 2) {
for (i = 0; i < 4; i++)
c[3-i] = (i < autoCWSendReservCount ? byteToChar(autoCWSendReserv[i]) : ' ');
//display Sending Index
c[4] = byteToChar(sendingCWTextIndex);
c[5] = '=';
}
else {
if (cwTimeout > 0)
strcpy(c, " CW:");
else
strcpy(c, " TX:");
}
}
else {
if (ritOn)
strcpy(c, "RIT ");
else {
if (cwMode == 0)
{
if (isUSB)
strcpy(c, "USB ");
else
strcpy(c, "LSB ");
}
else if (cwMode == 1)
{
strcpy(c, "CWL ");
}
else
{
strcpy(c, "CWU ");
}
}
if (vfoActive == VFO_A) // VFO A is active
strcat(c, "A:");
else
strcat(c, "B:");
}
//Fixed by Mitani Massaru (JE4SMQ)
if (isShiftDisplayCWFreq == 1)
{
if (cwMode == 1) //CWL
tmpFreq = tmpFreq - sideTone + shiftDisplayAdjustVal;
else if (cwMode == 2) //CWU
tmpFreq = tmpFreq + sideTone + shiftDisplayAdjustVal;
}
//display frequency
for (int i = 15; i >= 6; i--) {
if (tmpFreq > 0) {
if (i == 12 || i == 8) c[i] = '.';
else {
c[i] = tmpFreq % 10 + 0x30;
tmpFreq /= 10;
}
}
else
c[i] = ' ';
}
//remarked by KD8CEC
//already RX/TX status display, and over index (16 x 2 LCD)
//if (inTx)
// strcat(c, " TX");
printLine(1, c);
byte diplayVFOLine = 1;
if ((displayOption1 & 0x01) == 0x01)
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_Write(0x7E);
}
else
{
LCD_SetCursor(5,diplayVFOLine);
LCD_Write(':');
}
}
char line2Buffer[17];
//KD8CEC 200Hz ST
//L14.150 200Hz ST
//U14.150 +150khz
int freqScrollPosition = 0;
//Example Line2 Optinal Display
//immediate execution, not call by scheulder
//warning : unused parameter 'displayType' <-- ignore, this is reserve
void updateLine2Buffer(char displayType)
{
unsigned long tmpFreq = 0;
if (ritOn)
{
strcpy(line2Buffer, "RitTX:");
//display frequency
tmpFreq = ritTxFrequency;
//Fixed by Mitani Massaru (JE4SMQ)
if (isShiftDisplayCWFreq == 1)
{
if (cwMode == 1) //CWL
tmpFreq = tmpFreq - sideTone + shiftDisplayAdjustVal;
else if (cwMode == 2) //CWU
tmpFreq = tmpFreq + sideTone + shiftDisplayAdjustVal;
}
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;
}
else
{
tmpFreq = vfoB;
}
// 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] = 'M';
else
{
//example #2
if (freqScrollPosition++ > 18) //none scroll display time
{
line2Buffer[6] = 'M';
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] = ' ';
if (isIFShift)
{
// if (isDirectCall == 1)
// for (int i = 0; i < 16; i++)
// line2Buffer[i] = ' ';
//IFShift Offset Value
line2Buffer[8] = 'I';
line2Buffer[9] = 'F';
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 & Key Type 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 == 0)
{
line2Buffer[11] = 'H';
line2Buffer[12] = 'z';
}
line2Buffer[13] = ' ';
//Check CW Key cwKeyType = 0; //0: straight, 1 : iambica, 2: iambicb
if (sdrModeOn == 1)
{
line2Buffer[13] = 'S';
line2Buffer[14] = 'D';
line2Buffer[15] = 'R';
}
else 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);
int lineNumber = 0;
if ((displayOption1 & 0x01) == 0x01)
lineNumber = 1;
LCD_SetCursor(drawPosition, lineNumber);
//for (int i = 0; i <26; i++) //meter 5 + +db 1 = 6
LCD_Write(lcdMeter[0]);
LCD_Write(lcdMeter[1]);
}
}
byte testValue = 0;
char checkCount = 0;
char checkCountSMeter = 0;
int currentSMeter = 0;
byte scaledSMeter = 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;
*/
//S-Meter Display
if (((displayOption1 & 0x08) == 0x08 && (sdrModeOn == 0)) && (++checkCountSMeter > SMeterLatency))
{
int newSMeter;
//VK2ETA S-Meter from MAX9814 TC pin / divide 4 by KD8CEC for reduce EEPromSize
newSMeter = analogRead(ANALOG_SMETER);
//Faster attack, Slower release
currentSMeter = (newSMeter > currentSMeter ? ((currentSMeter * 3 + newSMeter * 7) + 5) / 10 : ((currentSMeter * 7 + newSMeter * 3) + 5) / 10) / 4;
scaledSMeter = 0;
for (byte s = 8; s >= 1; s--) {
if (currentSMeter > sMeterLevels[s]) {
scaledSMeter = s;
break;
}
}
DisplayMeter(0, scaledSMeter, 14);
checkCountSMeter = 0; //Reset Latency time
} //end of S-Meter
}
}
//AutoKey LCD Display Routine
void Display_AutoKeyTextIndex(byte textIndex)
{
byte diplayAutoCWLine = 0;
if ((displayOption1 & 0x01) == 0x01)
diplayAutoCWLine = 1;
LCD_SetCursor(0, diplayAutoCWLine);
LCD_Write(byteToChar(textIndex));
LCD_Write(':');
}
void DisplayCallsign(byte callSignLength)
{
printLineFromEEPRom(0, 0, 0, userCallsignLength -1, 0); //eeprom to lcd use offset (USER_CALLSIGN_DAT)
//delay(500);
}
void DisplayVersionInfo(const __FlashStringHelper * fwVersionInfo)
{
printLineF(1, fwVersionInfo);
}
#endif

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/*************************************************************************
KD8CEC's uBITX Display Routine for LCD1602 Dual LCD by KD8CEC
1.This is the display code for the default LCD mounted in uBITX.
2.Display related functions of uBITX. Some functions moved from uBITX_Ui.
3.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/>.
**************************************************************************/
#include "ubitx.h"
//Common Defines *********************************************************
#define LCD_CLEARDISPLAY 0x01
#define LCD_RETURNHOME 0x02
#define LCD_ENTRYMODESET 0x04
#define LCD_DISPLAYCONTROL 0x08
#define LCD_CURSORSHIFT 0x10
#define LCD_FUNCTIONSET 0x20
#define LCD_SETCGRAMADDR 0x40
#define LCD_SETDDRAMADDR 0x80
// flags for display entry mode
#define LCD_ENTRYRIGHT 0x00
#define LCD_ENTRYLEFT 0x02
#define LCD_ENTRYSHIFTINCREMENT 0x01
#define LCD_ENTRYSHIFTDECREMENT 0x00
// flags for display on/off control
#define LCD_DISPLAYON 0x04
#define LCD_DISPLAYOFF 0x00
#define LCD_CURSORON 0x02
#define LCD_CURSOROFF 0x00
#define LCD_BLINKON 0x01
#define LCD_BLINKOFF 0x00
// flags for display/cursor shift
#define LCD_DISPLAYMOVE 0x08
#define LCD_CURSORMOVE 0x00
#define LCD_MOVERIGHT 0x04
#define LCD_MOVELEFT 0x00
// flags for function set
#define LCD_8BITMODE 0x10
#define LCD_4BITMODE 0x00
#define LCD_2LINE 0x08
#define LCD_1LINE 0x00
#define LCD_5x10DOTS 0x04
#define LCD_5x8DOTS 0x00
// flags for backlight control
#define LCD_BACKLIGHT 0x08
#define LCD_NOBACKLIGHT 0x00
//========================================================================
//Begin of I2CTinyLCD Library for Dual LCD by KD8CEC
//========================================================================
#ifdef UBITX_DISPLAY_LCD1602I_DUAL
#include <Wire.h>
/*************************************************************************
I2C Tiny LCD Library
Referecnce Source : LiquidCrystal_I2C.cpp // Based on the work by DFRobot
KD8CEC
This source code is modified version for small program memory
from Arduino LiquidCrystal_I2C Library
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.
Ian KD8CEC
**************************************************************************/
#define UBITX_DISPLAY_LCD1602_BASE
#define En B00000100 // Enable bit
#define Rw B00000010 // Read/Write bit
#define Rs B00000001 // Register select bit
#define LCD_Command(x) (LCD_Send(x, 0))
#define LCD_Write(x) (LCD_Send(x, Rs))
uint8_t _Addr;
uint8_t _displayfunction;
uint8_t _displaycontrol;
uint8_t _displaymode;
uint8_t _numlines;
uint8_t _cols;
uint8_t _rows;
uint8_t _backlightval;
#define printIIC(args) Wire.write(args)
void expanderWrite(uint8_t _data)
{
Wire.beginTransmission(_Addr);
printIIC((int)(_data) | _backlightval);
Wire.endTransmission();
}
void pulseEnable(uint8_t _data){
expanderWrite(_data | En); // En high
delayMicroseconds(1); // enable pulse must be >450ns
expanderWrite(_data & ~En); // En low
delayMicroseconds(50); // commands need > 37us to settle
}
void write4bits(uint8_t value)
{
expanderWrite(value);
pulseEnable(value);
}
void LCD_Send(uint8_t value, uint8_t mode)
{
uint8_t highnib=value&0xf0;
uint8_t lownib=(value<<4)&0xf0;
write4bits((highnib)|mode);
write4bits((lownib)|mode);
}
// Turn the (optional) backlight off/on
void noBacklight(void) {
_backlightval=LCD_NOBACKLIGHT;
expanderWrite(0);
}
void backlight(void) {
_backlightval=LCD_BACKLIGHT;
expanderWrite(0);
}
void LCD1602_Dual_Init()
{
//I2C Init
_cols = 16;
_rows = 2;
_backlightval = LCD_NOBACKLIGHT;
Wire.begin();
delay(50);
// Now we pull both RS and R/W low to begin commands
_Addr = I2C_LCD_MASTER_ADDRESS;
expanderWrite(_backlightval); // reset expanderand turn backlight off (Bit 8 =1)
_Addr = I2C_LCD_SECOND_ADDRESS;
expanderWrite(_backlightval); // reset expanderand turn backlight off (Bit 8 =1)
delay(1000);
//put the LCD into 4 bit mode
// this is according to the hitachi HD44780 datasheet
// figure 24, pg 46
_Addr = I2C_LCD_MASTER_ADDRESS;
// we start in 8bit mode, try to set 4 bit mode
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// second try
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// third go!
write4bits(0x03 << 4);
delayMicroseconds(150);
// finally, set to 4-bit interface
write4bits(0x02 << 4);
// finally, set # lines, font size, etc.
LCD_Command(LCD_FUNCTIONSET | LCD_4BITMODE | LCD_1LINE | LCD_5x8DOTS | LCD_2LINE);
// turn the display on with no cursor or blinking default
LCD_Command(LCD_DISPLAYCONTROL | LCD_DISPLAYON | LCD_CURSOROFF | LCD_BLINKOFF);
// clear it off
LCD_Command(LCD_CLEARDISPLAY); // clear display, set cursor position to zero
//delayMicroseconds(2000); // this command takes a long time!
delayMicroseconds(1000); // this command takes a long time!
LCD_Command(LCD_ENTRYMODESET | LCD_ENTRYLEFT | LCD_ENTRYSHIFTDECREMENT);
backlight();
_Addr = I2C_LCD_SECOND_ADDRESS;
// we start in 8bit mode, try to set 4 bit mode
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// second try
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// third go!
write4bits(0x03 << 4);
delayMicroseconds(150);
// finally, set to 4-bit interface
write4bits(0x02 << 4);
// finally, set # lines, font size, etc.
LCD_Command(LCD_FUNCTIONSET | LCD_4BITMODE | LCD_1LINE | LCD_5x8DOTS | LCD_2LINE);
// turn the display on with no cursor or blinking default
LCD_Command(LCD_DISPLAYCONTROL | LCD_DISPLAYON | LCD_CURSOROFF | LCD_BLINKOFF);
// clear it off
LCD_Command(LCD_CLEARDISPLAY); // clear display, set cursor position to zero
//delayMicroseconds(2000); // this command takes a long time!
delayMicroseconds(1000); // this command takes a long time!
LCD_Command(LCD_ENTRYMODESET | LCD_ENTRYLEFT | LCD_ENTRYSHIFTDECREMENT);
backlight();
//Change to Default LCD (Master)
_Addr = I2C_LCD_MASTER_ADDRESS;
}
//========================================================================
// 16 X 02 LCD Routines
//Begin of Display Base Routines (Init, printLine..)
//========================================================================
void LCD_Print(const char *c)
{
for (uint8_t i = 0; i < strlen(c); i++)
{
if (*(c + i) == 0x00) return;
LCD_Write(*(c + i));
}
}
const int row_offsets[] = { 0x00, 0x40, 0x14, 0x54 };
void LCD_SetCursor(uint8_t col, uint8_t row)
{
LCD_Command(LCD_SETDDRAMADDR | (col + row_offsets[row])); //0 : 0x00, 1 : 0x40, only for 20 x 4 lcd
}
void LCD_CreateChar(uint8_t location, uint8_t charmap[])
{
location &= 0x7; // we only have 8 locations 0-7
LCD_Command(LCD_SETCGRAMADDR | (location << 3));
for (int i=0; i<8; i++)
LCD_Write(charmap[i]);
}
//SWR GRAPH, DrawMeter and drawingMeter Logic function by VK2ETA
//#define OPTION_SKINNYBARS
char c[30], b[30];
char printBuff[4][20]; //mirrors what is showing on the two lines of the display
void LCD_Init(void)
{
LCD1602_Dual_Init();
_Addr = I2C_LCD_SECOND_ADDRESS;
initMeter(); //for Meter Display //when dual LCD, S.Meter on second LCD
_Addr = I2C_LCD_MASTER_ADDRESS;
}
// 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
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);
strcpy(printBuff[linenmbr], c);
for (byte i = strlen(c); i < 20; i++) { // add white spaces until the end of the 20 characters line is reached
LCD_Write(' ');
}
}
}
void printLineF(char linenmbr, const __FlashStringHelper *c)
{
int i;
char tmpBuff[21];
PGM_P p = reinterpret_cast<PGM_P>(c);
for (i = 0; i < 21; i++){
unsigned char fChar = pgm_read_byte(p++);
tmpBuff[i] = fChar;
if (fChar == 0)
break;
}
printLine(linenmbr, tmpBuff);
}
#define LCD_MAX_COLUMN 20
void printLineFromEEPRom(char linenmbr, char lcdColumn, byte eepromStartIndex, byte eepromEndIndex, char offsetTtype) {
if ((displayOption1 & 0x01) == 0x01)
linenmbr = (linenmbr == 0 ? 1 : 0); //Line Toggle
LCD_SetCursor(lcdColumn, linenmbr);
for (byte i = eepromStartIndex; i <= eepromEndIndex; i++)
{
if (++lcdColumn <= LCD_MAX_COLUMN)
LCD_Write(EEPROM.read((offsetTtype == 0 ? USER_CALLSIGN_DAT : WSPR_MESSAGE1) + i));
else
break;
}
for (byte i = lcdColumn; i < 20; i++) //Right Padding by Space
LCD_Write(' ');
}
// short cut to print to the first line
void printLine1(const char *c)
{
printLine(1,c);
}
// short cut to print to the first line
void printLine2(const char *c)
{
printLine(0,c);
}
void clearLine2()
{
printLine2("");
line2DisplayStatus = 0;
}
// short cut to print to the first line
void printLine1Clear(){
printLine(1,"");
}
// short cut to print to the first line
void printLine2Clear(){
printLine(0, "");
}
void printLine2ClearAndUpdate(){
printLine(0, "");
line2DisplayStatus = 0;
updateDisplay();
}
//==================================================================================
//End of Display Base Routines
//==================================================================================
//==================================================================================
//Begin of User Interface Routines
//==================================================================================
//Main Display
// this builds up the top line of the display with frequency and mode
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
// i also Very TNX Purdum for good source code
int i;
unsigned long tmpFreq = frequency; //
memset(c, 0, sizeof(c));
if (inTx){
if (isCWAutoMode == 2) {
for (i = 0; i < 4; i++)
c[3-i] = (i < autoCWSendReservCount ? byteToChar(autoCWSendReserv[i]) : ' ');
//display Sending Index
c[4] = byteToChar(sendingCWTextIndex);
c[5] = '=';
}
else {
if (cwTimeout > 0)
strcpy(c, " CW:");
else
strcpy(c, " TX:");
}
}
else {
if (ritOn)
strcpy(c, "RIT ");
else {
if (cwMode == 0)
{
if (isUSB)
strcpy(c, "USB ");
else
strcpy(c, "LSB ");
}
else if (cwMode == 1)
{
strcpy(c, "CWL ");
}
else
{
strcpy(c, "CWU ");
}
}
if (vfoActive == VFO_A) // VFO A is active
strcat(c, "A:");
else
strcat(c, "B:");
}
//Fixed by Mitani Massaru (JE4SMQ)
if (isShiftDisplayCWFreq == 1)
{
if (cwMode == 1) //CWL
tmpFreq = tmpFreq - sideTone + shiftDisplayAdjustVal;
else if (cwMode == 2) //CWU
tmpFreq = tmpFreq + sideTone + shiftDisplayAdjustVal;
}
//display frequency
for (int i = 15; i >= 6; i--) {
if (tmpFreq > 0) {
if (i == 12 || i == 8) c[i] = '.';
else {
c[i] = tmpFreq % 10 + 0x30;
tmpFreq /= 10;
}
}
else
c[i] = ' ';
}
//remarked by KD8CEC
//already RX/TX status display, and over index (16 x 2 LCD)
printLine(1, c);
byte diplayVFOLine = 1;
if ((displayOption1 & 0x01) == 0x01)
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_Write(0x7E);
}
else
{
LCD_SetCursor(5,diplayVFOLine);
LCD_Write(':');
}
}
char line2Buffer[20];
//KD8CEC 200Hz ST
//L14.150 200Hz ST
//U14.150 +150khz
int freqScrollPosition = 0;
//Example Line2 Optinal Display
//immediate execution, not call by scheulder
//warning : unused parameter 'displayType' <-- ignore, this is reserve
void updateLine2Buffer(char displayType)
{
unsigned long tmpFreq = 0;
if (ritOn)
{
strcpy(line2Buffer, "RitTX:");
//display frequency
tmpFreq = ritTxFrequency;
//Fixed by Mitani Massaru (JE4SMQ)
if (isShiftDisplayCWFreq == 1)
{
if (cwMode == 1) //CWL
tmpFreq = tmpFreq - sideTone + shiftDisplayAdjustVal;
else if (cwMode == 2) //CWU
tmpFreq = tmpFreq + sideTone + shiftDisplayAdjustVal;
}
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;
}
else
{
tmpFreq = vfoB;
}
// 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] = ' ';
}
memset(&line2Buffer[10], ' ', 10);
if (isIFShift)
{
line2Buffer[6] = 'M';
line2Buffer[7] = ' ';
//IFShift Offset Value
line2Buffer[8] = 'I';
line2Buffer[9] = 'F';
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);
for (int i = 12; i < 17; i++)
{
if (line2Buffer[i] == 0)
line2Buffer[i] = ' ';
}
} // end of display IF
else // step & Key Type display
{
//Step
long tmpStep = arTuneStep[tuneStepIndex -1];
byte isStepKhz = 0;
if (tmpStep >= 1000)
{
isStepKhz = 2;
}
for (int i = 13; i >= 11 - isStepKhz; i--) {
if (tmpStep > 0) {
line2Buffer[i + isStepKhz] = tmpStep % 10 + 0x30;
tmpStep /= 10;
}
else
line2Buffer[i +isStepKhz] = ' ';
}
if (isStepKhz == 0)
{
line2Buffer[14] = 'H';
line2Buffer[15] = 'z';
}
}
//line2Buffer[17] = ' ';
/* ianlee
//Check CW Key cwKeyType = 0; //0: straight, 1 : iambica, 2: iambicb
if (cwKeyType == 0)
{
line2Buffer[18] = 'S';
line2Buffer[19] = 'T';
}
else if (cwKeyType == 1)
{
line2Buffer[18] = 'I';
line2Buffer[19] = 'A';
}
else
{
line2Buffer[18] = 'I';
line2Buffer[19] = '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);
LCD_SetCursor(drawPosition, 0);
LCD_Write('S');
LCD_Write(':');
for (int i = 0; i < 6; i++) //meter 5 + +db 1 = 6
LCD_Write(lcdMeter[i]);
}
}
byte testValue = 0;
char checkCount = 0;
int currentSMeter = 0;
byte scaledSMeter = 0;
char checkCountSMeter = 0;
char beforeKeyType = -1;
char displaySDRON = 0;
//execute interval : 0.25sec
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;
//check change CW Key Type
if (beforeKeyType != cwKeyType)
{
_Addr = I2C_LCD_SECOND_ADDRESS;
LCD_SetCursor(10, 0);
LCD_Write('K');
LCD_Write('E');
LCD_Write('Y');
LCD_Write(':');
//Check CW Key cwKeyType = 0; //0: straight, 1 : iambica, 2: iambicb
if (cwKeyType == 0)
{
LCD_Write('S');
LCD_Write('T');
}
else if (cwKeyType == 1)
{
LCD_Write('I');
LCD_Write('A');
}
else
{
LCD_Write('I');
LCD_Write('B');
}
beforeKeyType = cwKeyType;
_Addr = I2C_LCD_MASTER_ADDRESS;
} //Display Second Screen
}
}
//EX for Meters
//S-Meter Display
_Addr = I2C_LCD_SECOND_ADDRESS;
if (sdrModeOn == 1)
{
if (displaySDRON == 0) //once display
{
displaySDRON = 1;
LCD_SetCursor(0, 0);
LCD_Write('S');
LCD_Write('D');
LCD_Write('R');
LCD_Write(' ');
LCD_Write('M');
LCD_Write('O');
LCD_Write('D');
LCD_Write('E');
}
}
else if (((displayOption1 & 0x08) == 0x08) && (++checkCountSMeter > 3))
{
int newSMeter;
displaySDRON = 0;
//VK2ETA S-Meter from MAX9814 TC pin
newSMeter = analogRead(ANALOG_SMETER);
//Faster attack, Slower release
//currentSMeter = (newSMeter > currentSMeter ? ((currentSMeter * 3 + newSMeter * 7) + 5) / 10 : ((currentSMeter * 7 + newSMeter * 3) + 5) / 10);
currentSMeter = (currentSMeter * 3 + newSMeter * 7) / 10; //remarked becaused of have already Latency time
scaledSMeter = 0;
for (byte s = 8; s >= 1; s--) {
if (currentSMeter > sMeterLevels[s]) {
scaledSMeter = s;
break;
}
}
DisplayMeter(0, scaledSMeter, 0);
checkCountSMeter = 0;
} //end of S-Meter
_Addr = I2C_LCD_MASTER_ADDRESS;
}
}
//AutoKey LCD Display Routine
void Display_AutoKeyTextIndex(byte textIndex)
{
byte diplayAutoCWLine = 0;
if ((displayOption1 & 0x01) == 0x01)
diplayAutoCWLine = 1;
LCD_SetCursor(0, diplayAutoCWLine);
LCD_Write(byteToChar(textIndex));
LCD_Write(':');
}
void DisplayCallsign(byte callSignLength)
{
_Addr = I2C_LCD_SECOND_ADDRESS;
printLineFromEEPRom(1, 16 - userCallsignLength, 0, userCallsignLength -1, 0); //eeprom to lcd use offset (USER_CALLSIGN_DAT)
_Addr = I2C_LCD_MASTER_ADDRESS;
}
void DisplayVersionInfo(const __FlashStringHelper * fwVersionInfo)
{
_Addr = I2C_LCD_SECOND_ADDRESS;
printLineF(1, fwVersionInfo);
_Addr = I2C_LCD_MASTER_ADDRESS;
}
#endif

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/*************************************************************************
KD8CEC's uBITX Display Routine for LCD2004 Parrel
1.This is the display code for the default LCD mounted in uBITX.
2.Display related functions of uBITX. Some functions moved from uBITX_Ui.
3.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/>.
**************************************************************************/
#include "ubitx.h"
//Common Defines *********************************************************
#define LCD_CLEARDISPLAY 0x01
#define LCD_RETURNHOME 0x02
#define LCD_ENTRYMODESET 0x04
#define LCD_DISPLAYCONTROL 0x08
#define LCD_CURSORSHIFT 0x10
#define LCD_FUNCTIONSET 0x20
#define LCD_SETCGRAMADDR 0x40
#define LCD_SETDDRAMADDR 0x80
// flags for display entry mode
#define LCD_ENTRYRIGHT 0x00
#define LCD_ENTRYLEFT 0x02
#define LCD_ENTRYSHIFTINCREMENT 0x01
#define LCD_ENTRYSHIFTDECREMENT 0x00
// flags for display on/off control
#define LCD_DISPLAYON 0x04
#define LCD_DISPLAYOFF 0x00
#define LCD_CURSORON 0x02
#define LCD_CURSOROFF 0x00
#define LCD_BLINKON 0x01
#define LCD_BLINKOFF 0x00
// flags for display/cursor shift
#define LCD_DISPLAYMOVE 0x08
#define LCD_CURSORMOVE 0x00
#define LCD_MOVERIGHT 0x04
#define LCD_MOVELEFT 0x00
// flags for function set
#define LCD_8BITMODE 0x10
#define LCD_4BITMODE 0x00
#define LCD_2LINE 0x08
#define LCD_1LINE 0x00
#define LCD_5x10DOTS 0x04
#define LCD_5x8DOTS 0x00
// flags for backlight control
#define LCD_BACKLIGHT 0x08
#define LCD_NOBACKLIGHT 0x00
//========================================================================
//Begin of TinyLCD Library by KD8CEC
//========================================================================
#ifdef UBITX_DISPLAY_LCD2004P
/*************************************************************************
LCD2004TINY Library for 20 x 4 LCD
Referecnce Source : LiquidCrystal.cpp
KD8CEC
This source code is modified version for small program memory
from Arduino LiquidCrystal Library
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
**************************************************************************/
#define LCD_Command(x) (LCD_Send(x, LOW))
#define LCD_Write(x) (LCD_Send(x, HIGH))
#define UBITX_DISPLAY_LCD2004_BASE
//Define connected PIN
#define LCD_PIN_RS 8
#define LCD_PIN_EN 9
uint8_t LCD_PIN_DAT[4] = {10, 11, 12, 13};
void write4bits(uint8_t value)
{
for (int i = 0; i < 4; i++)
digitalWrite(LCD_PIN_DAT[i], (value >> i) & 0x01);
digitalWrite(LCD_PIN_EN, LOW);
delayMicroseconds(1);
digitalWrite(LCD_PIN_EN, HIGH);
delayMicroseconds(1); // enable pulse must be >450ns
digitalWrite(LCD_PIN_EN, LOW);
delayMicroseconds(100); // commands need > 37us to settle
}
void LCD_Send(uint8_t value, uint8_t mode)
{
digitalWrite(LCD_PIN_RS, mode);
write4bits(value>>4);
write4bits(value);
}
void LCD2004_Init()
{
pinMode(LCD_PIN_RS, OUTPUT);
pinMode(LCD_PIN_EN, OUTPUT);
for (int i = 0; i < 4; i++)
pinMode(LCD_PIN_DAT[i], OUTPUT);
delayMicroseconds(50);
// Now we pull both RS and R/W low to begin commands
digitalWrite(LCD_PIN_RS, LOW);
digitalWrite(LCD_PIN_EN, LOW);
// we start in 8bit mode, try to set 4 bit mode
write4bits(0x03);
delayMicroseconds(4500); // wait min 4.1ms
// second try
write4bits(0x03);
delayMicroseconds(4500); // wait min 4.1ms
// third go!
write4bits(0x03);
delayMicroseconds(150);
// finally, set to 4-bit interface
write4bits(0x02);
// finally, set # lines, font size, etc.
LCD_Command(LCD_FUNCTIONSET | LCD_4BITMODE | LCD_1LINE | LCD_5x8DOTS | LCD_2LINE);
// turn the display on with no cursor or blinking default
LCD_Command(LCD_DISPLAYCONTROL | LCD_DISPLAYON | LCD_CURSOROFF | LCD_BLINKOFF);
// clear it off
LCD_Command(LCD_CLEARDISPLAY); // clear display, set cursor position to zero
delayMicroseconds(2000); // this command takes a long time!
LCD_Command(LCD_ENTRYMODESET | LCD_ENTRYLEFT | LCD_ENTRYSHIFTDECREMENT);
}
#endif
//========================================================================
//End of TinyLCD Library by KD8CEC
//========================================================================
//========================================================================
//Begin of I2CTinyLCD Library by KD8CEC
//========================================================================
#ifdef UBITX_DISPLAY_LCD2004I
#include <Wire.h>
/*************************************************************************
I2C Tiny LCD Library
Referecnce Source : LiquidCrystal_I2C.cpp // Based on the work by DFRobot
KD8CEC
This source code is modified version for small program memory
from Arduino LiquidCrystal_I2C Library
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.
Ian KD8CEC
**************************************************************************/
#define UBITX_DISPLAY_LCD2004_BASE
#define En B00000100 // Enable bit
#define Rw B00000010 // Read/Write bit
#define Rs B00000001 // Register select bit
#define LCD_Command(x) (LCD_Send(x, 0))
#define LCD_Write(x) (LCD_Send(x, Rs))
uint8_t _Addr;
uint8_t _displayfunction;
uint8_t _displaycontrol;
uint8_t _displaymode;
uint8_t _numlines;
uint8_t _cols;
uint8_t _rows;
uint8_t _backlightval;
#define printIIC(args) Wire.write(args)
void expanderWrite(uint8_t _data)
{
Wire.beginTransmission(_Addr);
printIIC((int)(_data) | _backlightval);
Wire.endTransmission();
}
void pulseEnable(uint8_t _data){
expanderWrite(_data | En); // En high
delayMicroseconds(1); // enable pulse must be >450ns
expanderWrite(_data & ~En); // En low
delayMicroseconds(50); // commands need > 37us to settle
}
void write4bits(uint8_t value)
{
expanderWrite(value);
pulseEnable(value);
}
void LCD_Send(uint8_t value, uint8_t mode)
{
uint8_t highnib=value&0xf0;
uint8_t lownib=(value<<4)&0xf0;
write4bits((highnib)|mode);
write4bits((lownib)|mode);
}
// Turn the (optional) backlight off/on
void noBacklight(void) {
_backlightval=LCD_NOBACKLIGHT;
expanderWrite(0);
}
void backlight(void) {
_backlightval=LCD_BACKLIGHT;
expanderWrite(0);
}
void LCD2004_Init()
{
//I2C Init
_Addr = I2C_LCD_MASTER_ADDRESS;
_cols = 20;
_rows = 4;
_backlightval = LCD_NOBACKLIGHT;
Wire.begin();
delay(50);
// Now we pull both RS and R/W low to begin commands
expanderWrite(_backlightval); // reset expanderand turn backlight off (Bit 8 =1)
delay(1000);
//put the LCD into 4 bit mode
// this is according to the hitachi HD44780 datasheet
// figure 24, pg 46
// we start in 8bit mode, try to set 4 bit mode
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// second try
write4bits(0x03 << 4);
delayMicroseconds(4500); // wait min 4.1ms
// third go!
write4bits(0x03 << 4);
delayMicroseconds(150);
// finally, set to 4-bit interface
write4bits(0x02 << 4);
// finally, set # lines, font size, etc.
LCD_Command(LCD_FUNCTIONSET | LCD_4BITMODE | LCD_1LINE | LCD_5x8DOTS | LCD_2LINE);
// turn the display on with no cursor or blinking default
LCD_Command(LCD_DISPLAYCONTROL | LCD_DISPLAYON | LCD_CURSOROFF | LCD_BLINKOFF);
// clear it off
LCD_Command(LCD_CLEARDISPLAY); // clear display, set cursor position to zero
//delayMicroseconds(2000); // this command takes a long time!
delayMicroseconds(1000); // this command takes a long time!
LCD_Command(LCD_ENTRYMODESET | LCD_ENTRYLEFT | LCD_ENTRYSHIFTDECREMENT);
backlight();
}
#endif
//========================================================================
//End of I2CTinyLCD Library by KD8CEC
//========================================================================
//========================================================================
// 20 X 04 LCD Routines
//Begin of Display Base Routines (Init, printLine..)
//========================================================================
#ifdef UBITX_DISPLAY_LCD2004_BASE
void LCD_Print(const char *c)
{
for (uint8_t i = 0; i < strlen(c); i++)
{
if (*(c + i) == 0x00) return;
LCD_Write(*(c + i));
}
}
const int row_offsets[] = { 0x00, 0x40, 0x14, 0x54 };
void LCD_SetCursor(uint8_t col, uint8_t row)
{
LCD_Command(LCD_SETDDRAMADDR | (col + row_offsets[row])); //0 : 0x00, 1 : 0x40, only for 20 x 4 lcd
}
void LCD_CreateChar(uint8_t location, uint8_t charmap[])
{
location &= 0x7; // we only have 8 locations 0-7
LCD_Command(LCD_SETCGRAMADDR | (location << 3));
for (int i=0; i<8; i++)
LCD_Write(charmap[i]);
}
//SWR GRAPH, DrawMeter and drawingMeter Logic function by VK2ETA
//#define OPTION_SKINNYBARS
char c[30], b[30];
char printBuff[4][21]; //mirrors what is showing on the two lines of the display
void LCD_Init(void)
{
LCD2004_Init();
initMeter(); //for Meter Display
}
// 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
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);
strcpy(printBuff[linenmbr], c);
for (byte i = strlen(c); i < 20; i++) { // add white spaces until the end of the 20 characters line is reached
LCD_Write(' ');
}
}
}
void printLineF(char linenmbr, const __FlashStringHelper *c)
{
int i;
char tmpBuff[21];
PGM_P p = reinterpret_cast<PGM_P>(c);
for (i = 0; i < 21; i++){
unsigned char fChar = pgm_read_byte(p++);
tmpBuff[i] = fChar;
if (fChar == 0)
break;
}
printLine(linenmbr, tmpBuff);
}
#define LCD_MAX_COLUMN 20
void printLineFromEEPRom(char linenmbr, char lcdColumn, byte eepromStartIndex, byte eepromEndIndex, char offsetTtype) {
if ((displayOption1 & 0x01) == 0x01)
linenmbr = (linenmbr == 0 ? 1 : 0); //Line Toggle
LCD_SetCursor(lcdColumn, linenmbr);
for (byte i = eepromStartIndex; i <= eepromEndIndex; i++)
{
if (++lcdColumn <= LCD_MAX_COLUMN)
LCD_Write(EEPROM.read((offsetTtype == 0 ? USER_CALLSIGN_DAT : WSPR_MESSAGE1) + i));
else
break;
}
for (byte i = lcdColumn; i < 20; i++) //Right Padding by Space
LCD_Write(' ');
}
// short cut to print to the first line
void printLine1(const char *c)
{
printLine(1,c);
}
// short cut to print to the first line
void printLine2(const char *c)
{
printLine(0,c);
}
void clearLine2()
{
printLine2("");
line2DisplayStatus = 0;
}
// short cut to print to the first line
void printLine1Clear(){
printLine(1,"");
}
// short cut to print to the first line
void printLine2Clear(){
printLine(0, "");
}
void printLine2ClearAndUpdate(){
printLine(0, "");
line2DisplayStatus = 0;
updateDisplay();
}
//==================================================================================
//End of Display Base Routines
//==================================================================================
//==================================================================================
//Begin of User Interface Routines
//==================================================================================
//Main Display
// this builds up the top line of the display with frequency and mode
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
// i also Very TNX Purdum for good source code
int i;
unsigned long tmpFreq = frequency; //
memset(c, 0, sizeof(c));
if (inTx){
if (isCWAutoMode == 2) {
for (i = 0; i < 4; i++)
c[3-i] = (i < autoCWSendReservCount ? byteToChar(autoCWSendReserv[i]) : ' ');
//display Sending Index
c[4] = byteToChar(sendingCWTextIndex);
c[5] = '=';
}
else {
if (cwTimeout > 0)
strcpy(c, " CW:");
else
strcpy(c, " TX:");
}
}
else {
if (ritOn)
strcpy(c, "RIT ");
else {
if (cwMode == 0)
{
if (isUSB)
strcpy(c, "USB ");
else
strcpy(c, "LSB ");
}
else if (cwMode == 1)
{
strcpy(c, "CWL ");
}
else
{
strcpy(c, "CWU ");
}
}
if (vfoActive == VFO_A) // VFO A is active
strcat(c, "A:");
else
strcat(c, "B:");
}
//Fixed by Mitani Massaru (JE4SMQ)
if (isShiftDisplayCWFreq == 1)
{
if (cwMode == 1) //CWL
tmpFreq = tmpFreq - sideTone + shiftDisplayAdjustVal;
else if (cwMode == 2) //CWU
tmpFreq = tmpFreq + sideTone + shiftDisplayAdjustVal;
}
//display frequency
for (int i = 15; i >= 6; i--) {
if (tmpFreq > 0) {
if (i == 12 || i == 8) c[i] = '.';
else {
c[i] = tmpFreq % 10 + 0x30;
tmpFreq /= 10;
}
}
else
c[i] = ' ';
}
if (sdrModeOn)
strcat(c, " SDR");
else
strcat(c, " SPK");
//remarked by KD8CEC
//already RX/TX status display, and over index (20 x 4 LCD)
//if (inTx)
// strcat(c, " TX");
printLine(1, c);
byte diplayVFOLine = 1;
if ((displayOption1 & 0x01) == 0x01)
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_Write(0x7E);
}
else
{
LCD_SetCursor(5,diplayVFOLine);
LCD_Write(':');
}
}
char line2Buffer[20];
//KD8CEC 200Hz ST
//L14.150 200Hz ST
//U14.150 +150khz
int freqScrollPosition = 0;
//Example Line2 Optinal Display
//immediate execution, not call by scheulder
//warning : unused parameter 'displayType' <-- ignore, this is reserve
void updateLine2Buffer(char displayType)
{
unsigned long tmpFreq = 0;
if (ritOn)
{
strcpy(line2Buffer, "RitTX:");
//display frequency
tmpFreq = ritTxFrequency;
//Fixed by Mitani Massaru (JE4SMQ)
if (isShiftDisplayCWFreq == 1)
{
if (cwMode == 1) //CWL
tmpFreq = tmpFreq - sideTone + shiftDisplayAdjustVal;
else if (cwMode == 2) //CWU
tmpFreq = tmpFreq + sideTone + shiftDisplayAdjustVal;
}
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;
}
else
{
tmpFreq = vfoB;
}
// 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] = ' ';
}
memset(&line2Buffer[10], ' ', 10);
if (isIFShift)
{
line2Buffer[6] = 'M';
line2Buffer[7] = ' ';
//IFShift Offset Value
line2Buffer[8] = 'I';
line2Buffer[9] = 'F';
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);
for (int i = 12; i < 17; i++)
{
if (line2Buffer[i] == 0)
line2Buffer[i] = ' ';
}
} // end of display IF
else // step & Key Type display
{
//Step
long tmpStep = arTuneStep[tuneStepIndex -1];
byte isStepKhz = 0;
if (tmpStep >= 1000)
{
isStepKhz = 2;
}
for (int i = 14; i >= 12 - isStepKhz; i--) {
if (tmpStep > 0) {
line2Buffer[i + isStepKhz] = tmpStep % 10 + 0x30;
tmpStep /= 10;
}
else
line2Buffer[i +isStepKhz] = ' ';
}
if (isStepKhz == 0)
{
line2Buffer[15] = 'H';
line2Buffer[16] = 'z';
}
}
line2Buffer[17] = ' ';
//Check CW Key cwKeyType = 0; //0: straight, 1 : iambica, 2: iambicb
if (cwKeyType == 0)
{
line2Buffer[18] = 'S';
line2Buffer[19] = 'T';
}
else if (cwKeyType == 1)
{
line2Buffer[18] = 'I';
line2Buffer[19] = 'A';
}
else
{
line2Buffer[18] = 'I';
line2Buffer[19] = '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);
//int lineNumber = 0;
//if ((displayOption1 & 0x01) == 0x01)
//lineNumber = 1;
LCD_SetCursor(drawPosition, 2);
LCD_Write('S');
LCD_Write(':');
for (int i = 0; i < 6; i++) //meter 5 + +db 1 = 6
LCD_Write(lcdMeter[i]);
}
}
//meterType : 0 = S.Meter, 1 = Forward Power Meter, 2 = SWR Meter
void DisplayMeter(byte meterType, int meterValue, char drawPosition)
{
#ifdef OPTION_SKINNYBARS //We want skinny meter bars with more text/numbers
memcpy(&(line2Buffer[drawPosition]), " ", 8); //Blank that section of 8 characters first
if (meterType == 0) { //SWR meter
drawMeter(meterValue); //Only 2 characters
line2Buffer[drawPosition] = 'S';
byte sValue = round((float)meterValue * 1.5); //6 bars available only to show 9 S values
sValue = sValue > 9 ? 9 : sValue; //Max S9
line2Buffer[drawPosition + 1] = '0' + sValue; //0 to 9
memcpy(&(line2Buffer[drawPosition + 2]), lcdMeter, 2); //Copy the S-Meter bars
//Add the +10, +20, etc...
if (meterValue > 6) {
//We are over S9
line2Buffer[drawPosition + 4] = '+';
line2Buffer[drawPosition + 5] = '0' + meterValue - 6; //1,2,3 etc...
line2Buffer[drawPosition + 6] = '0';
}
} else if (meterType == 1) { //Forward Power
drawMeter(round((float)meterValue / 40)); //4 watts per bar
//meterValue contains power value x 10 (one decimal point)
line2Buffer[drawPosition] = 'P';
meterValue = meterValue > 999 ? 999 : meterValue; //Limit to 99.9 watts!!!!
//Remove decimal value and divide by 10
meterValue = round((float)meterValue / 10);
if (meterValue < 10) {
line2Buffer[drawPosition + 1] = ' ';
line2Buffer[drawPosition + 2] = '0' + meterValue; //0 to 9
} else {
line2Buffer[drawPosition + 1] = '0' + meterValue / 10;
line2Buffer[drawPosition + 2] = '0' + (meterValue - ((meterValue / 10) * 10));
}
line2Buffer[drawPosition + 3] = 'W';
memcpy(&(line2Buffer[drawPosition + 4]), lcdMeter, 2); //Copy the S-Meter bars
} else { //SWR
drawMeter((int)(((float)meterValue - 21) / 100)); //no bar = < 1.2, then 1 bar = 1.2 to 2.2, 2 bars = 2.2 to 3.2, etc...
//meterValue contains SWR x 100 (two decimal point)
memcpy(&(line2Buffer[drawPosition]), "SWR", 3);
meterValue = round((float)meterValue / 10); //We now have swr x 10 (1 decimal point)
if (meterValue < 100) { //10 to 99, no decimal point
//Draw the decimal value
line2Buffer[drawPosition + 3] = '0' + meterValue / 10;
line2Buffer[drawPosition + 4] = '.';
line2Buffer[drawPosition + 5] = '0' + (meterValue - ((meterValue / 10) * 10));
} else {
memcpy(&(line2Buffer[drawPosition + 3]), "10+", 3); //over 10
}
memcpy(&(line2Buffer[drawPosition + 6]), lcdMeter, 2); //Copy the S-Meter bars
}
#else //We want fat bars, easy to read, with less text/numbers
//Serial.print("In displaymeter, meterValue: "); Serial.println(meterValue);
drawMeter(meterValue);
//Always line 2
char sym = 'S';
if (meterType == 1) sym = 'P';
else if (meterType == 2) sym = 'R'; //For SWR
line2Buffer[drawPosition] = sym;
memcpy(&(line2Buffer[drawPosition + 1]), lcdMeter, 7);
#endif //OPTION_SKINNYBARS
}
byte testValue = 0;
char checkCount = 0;
int currentSMeter = 0;
//int sMeterLevels[] = {0, 5, 17, 41, 74, 140, 255, 365, 470};
byte scaledSMeter = 0;
char checkCountSMeter = 0;
//execute interval : 0.25sec
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++, 0);
if (testValue > 30)
testValue = 0;
*/
//Sample
//DisplayMeter(0, analogRead(ANALOG_SMETER) / 30, 0);
//DisplayMeter(0, analogRead(ANALOG_SMETER) / 10, 0);
//delay_background(10, 0);
//DisplayMeter(0, analogRead(ANALOG_SMETER), 0);
//if (testValue > 30)
// testValue = 0;
//S-Meter Display
if (((displayOption1 & 0x08) == 0x08 && (sdrModeOn == 0)) && (++checkCountSMeter > SMeterLatency))
{
int newSMeter;
//VK2ETA S-Meter from MAX9814 TC pin
newSMeter = analogRead(ANALOG_SMETER);
//Faster attack, Slower release
currentSMeter = (newSMeter > currentSMeter ? ((currentSMeter * 3 + newSMeter * 7) + 5) / 10 : ((currentSMeter * 7 + newSMeter * 3) + 5) / 10);
scaledSMeter = 0;
for (byte s = 8; s >= 1; s--) {
if (currentSMeter > sMeterLevels[s]) {
scaledSMeter = s;
break;
}
}
DisplayMeter(0, scaledSMeter, 0);
checkCountSMeter = 0; //Reset Latency time
} //end of S-Meter
}
}
//AutoKey LCD Display Routine
void Display_AutoKeyTextIndex(byte textIndex)
{
byte diplayAutoCWLine = 0;
if ((displayOption1 & 0x01) == 0x01)
diplayAutoCWLine = 1;
LCD_SetCursor(0, diplayAutoCWLine);
LCD_Write(byteToChar(textIndex));
LCD_Write(':');
}
void DisplayCallsign(byte callSignLength)
{
printLineFromEEPRom(3, 20 - userCallsignLength, 0, userCallsignLength -1, 0); //eeprom to lcd use offset (USER_CALLSIGN_DAT)
}
void DisplayVersionInfo(const __FlashStringHelper * fwVersionInfo)
{
printLineF(3, fwVersionInfo);
}
#endif

1560
ubitx_20/ubitx_menu.ino
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71
ubitx_20/ubitx_si5351.ino
View File

@@ -1,5 +1,20 @@
// ************* SI5315 routines - tks Jerry Gaffke, KE7ER ***********************
/************************************************************************************
* KD8CEC
* kd8cec@gmail.com http://www.hamskey.com
*
* Merge two SI5351 Librarys
* KE7ER's fixed vco and variable Clocks Configure values
* G3ZIL's fixed Clock Configure Value and variable VCO
* * I have combined the two libraries above. All licenses follow the above library.
*
* PLL-A is generated by fixing 850Mhz clock. All output clocks use PLL-A to
* generate the frequency. This is the method used in QRP radios such as uBITX.
* When switching to WSPR transmission mode, PLL-B operates for the base frequency to transmit WSPR.
* The output clock channel that controls the frequency is connected to the PLL-B.
* The WSPR protocol is generated by changing the clock of the PLL-B.
************************************************************************************/
// ************* SI5315 routines - tks Jerry Gaffke, KE7ER ***********************
// An minimalist standalone set of Si5351 routines.
// VCOA is fixed at 875mhz, VCOB not used.
// The output msynth dividers are used to generate 3 independent clocks
@@ -60,6 +75,7 @@ void i2cWriten(uint8_t reg, uint8_t *vals, uint8_t vcnt) { // write array
Wire.endTransmission();
}
uint8_t si5351Val[8] = {0, 1, 0, 0, 0, 0, 0, 0}; //for reduce program memory size
void si5351bx_init() { // Call once at power-up, start PLLA
uint32_t msxp1;
@@ -68,11 +84,13 @@ void si5351bx_init() { // Call once at power-up, start PLLA
i2cWrite(3, si5351bx_clken); // Disable all CLK output drivers
i2cWrite(183, SI5351BX_XTALPF << 6); // Set 25mhz crystal load capacitance
msxp1 = 128 * SI5351BX_MSA - 512; // and msxp2=0, msxp3=1, not fractional
uint8_t vals[8] = {0, 1, BB2(msxp1), BB1(msxp1), BB0(msxp1), 0, 0, 0};
i2cWriten(26, vals, 8); // Write to 8 PLLA msynth regs
//uint8_t vals[8] = {0, 1, BB2(msxp1), BB1(msxp1), BB0(msxp1), 0, 0, 0};
si5351Val[2] = BB2(msxp1);
si5351Val[3] = BB1(msxp1);
si5351Val[4] = BB0(msxp1);
i2cWriten(26, si5351Val, 8); // Write to 8 PLLA msynth regs
i2cWrite(177, 0x20); // Reset PLLA (0x80 resets PLLB)
// for (reg=16; reg<=23; reg++) i2cWrite(reg, 0x80); // Powerdown CLK's
// i2cWrite(187, 0); // No fannout of clkin, xtal, ms0, ms4
}
void si5351bx_setfreq(uint8_t clknum, uint32_t fout) { // Set a CLK to fout Hz
@@ -105,15 +123,50 @@ void si5351_set_calibration(int32_t cal){
si5351bx_setfreq(0, usbCarrier);
}
void SetCarrierFreq()
{
unsigned long appliedCarrier = ((cwMode == 0 ? usbCarrier : cwmCarrier) + (isIFShift && (inTx == 0) ? ifShiftValue : 0));
//si5351bx_setfreq(0, (sdrModeOn ? 0 : appliedCarrier));
si5351bx_setfreq(0, ((sdrModeOn && (inTx == 0)) ? 0 : appliedCarrier)); //found bug by KG4GEK
/*
if (cwMode == 0)
si5351bx_setfreq(0, usbCarrier + (isIFShift ? ifShiftValue : 0));
else
si5351bx_setfreq(0, cwmCarrier + (isIFShift ? ifShiftValue : 0));
*/
}
void initOscillators(){
//initialize the SI5351
si5351bx_init();
si5351bx_vcoa = (SI5351BX_XTAL * SI5351BX_MSA) + calibration; // apply the calibration correction factor
SetCarrierFreq();
}
if (cwMode == 0)
si5351bx_setfreq(0, usbCarrier + (isIFShift ? ifShiftValue : 0));
else
si5351bx_setfreq(0, cwmCarrier + (isIFShift ? ifShiftValue : 0));
//============================================================
// ADD FUNCTIONS by KD8CEC
//============================================================
uint8_t Wspr_Reg1[8] = {0xFF,0xFE, 0x00, 0, 0, 0, 0, 0}; //3, 4, 5, 6, 7
uint8_t Wspr_Reg2[8] = {0, 1, 0, 0, 0, 0, 0, 0}; //2, 3, 4
void Set_WSPR_Param(void)
{
i2cWrite(18, 128);
i2cWriten(34, Wspr_Reg1, 8);
i2cWriten(58, Wspr_Reg2, 8);
i2cWrite(177, 128);
i2cWrite(18, 111);
si5351bx_clken &= ~(1 << 2);
i2cWrite(3, si5351bx_clken);
}
void TXSubFreq(unsigned long P2)
{
i2cWrite(40, (P2 & 65280) >> 8);
i2cWrite(41, P2 & 255);
}

322
ubitx_20/ubitx_ui.ino
View File

@@ -5,38 +5,9 @@
* of the radio. Occasionally, it is used to provide a two-line information that is
* quickly cleared up.
*/
//#define printLineF1(x) (printLineF(1, x))
//#define printLineF2(x) (printLineF(0, x))
//returns true if the button is pressed
int btnDown(){
if (digitalRead(FBUTTON) == HIGH)
return 0;
else
return 1;
}
/**
* Meter (not used in this build for anything)
* the meter is drawn using special characters. Each character is composed of 5 x 8 matrix.
* The s_meter array holds the definition of the these characters.
* each line of the array is is one character such that 5 bits of every byte
* makes up one line of pixels of the that character (only 5 bits are used)
* The current reading of the meter is assembled in the string called meter
*/
/*
const PROGMEM uint8_t s_meter_bitmap[] = {
B00000,B00000,B00000,B00000,B00000,B00100,B00100,B11011,
B10000,B10000,B10000,B10000,B10100,B10100,B10100,B11011,
B01000,B01000,B01000,B01000,B01100,B01100,B01100,B11011,
B00100,B00100,B00100,B00100,B00100,B00100,B00100,B11011,
B00010,B00010,B00010,B00010,B00110,B00110,B00110,B11011,
B00001,B00001,B00001,B00001,B00101,B00101,B00101,B11011
};
*/
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
@@ -45,7 +16,35 @@ const PROGMEM uint8_t meters_bitmap[] = {
B11111, B11111, B11111, B11111, B11111, B11111, B11111, B11111 , //custom 5
B01000, B11100, B01000, B00000, B10111, B10101, B10101, B10111 //custom 6
};
*/
//SWR GRAPH, DrawMeter and drawingMeter Logic function by VK2ETA
#ifdef OPTION_SKINNYBARS //We want skninny bars with more text
//VK2ETA modded "Skinny" bitmaps
const PROGMEM uint8_t meters_bitmap[] = {
// B01110, B10001, B10001, B11111, B11011, B11011, B11111, B00000, //Padlock Symbol, for merging. Not working, see below
B00000, B00000, B00000, B00000, B00000, B00000, B00000, B10000, //shortest bar
B00000, B00000, B00000, B00000, B00000, B00000, B00100, B10100,
B00000, B00000, B00000, B00000, B00000, B00001, B00101, B10101,
B00000, B00000, B00000, B00000, B10000, B10000, B10000, B10000,
B00000, B00000, B00000, B00100, B10100, B10100, B10100, B10100,
B00000, B00000, B00001, B00101, B10101, B10101, B10101, B10101, //tallest bar
B00000, B00010, B00111, B00010, B01000, B11100, B01000, B00000, // ++ sign
};
#else
//VK2ETA "Fat" bars, easy to read, with less text
const PROGMEM uint8_t meters_bitmap[] = {
// B01110, B10001, B10001, B11111, B11011, B11011, B11111, B00000, //Padlock Symbol, for merging. Not working, see below
B00000, B00000, B00000, B00000, B00000, B00000, B00000, B11111, //shortest bar
B00000, B00000, B00000, B00000, B00000, B00000, B11111, B11111,
B00000, B00000, B00000, B00000, B00000, B11111, B11111, B11111,
B00000, B00000, B00000, B00000, B11111, B11111, B11111, B11111,
B00000, B00000, B00000, B11111, B11111, B11111, B11111, B11111,
B00000, B00000, B11111, B11111, B11111, B11111, B11111, B11111, //tallest bar
B00000, B00010, B00111, B00010, B01000, B11100, B01000, B00000, // ++ sign
};
#endif //OPTION_SKINNYBARS
PGM_P p_metes_bitmap = reinterpret_cast<PGM_P>(meters_bitmap);
const PROGMEM uint8_t lock_bitmap[8] = {
@@ -68,35 +67,41 @@ void initMeter(){
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(plock_bitmap + i);
lcd.createChar(0, tmpbytes);
LCD_CreateChar(0, tmpbytes);
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i);
lcd.createChar(1, tmpbytes);
LCD_CreateChar(1, tmpbytes);
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 8);
lcd.createChar(2, tmpbytes);
LCD_CreateChar(2, tmpbytes);
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 16);
lcd.createChar(3, tmpbytes);
LCD_CreateChar(3, tmpbytes);
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 24);
lcd.createChar(4, tmpbytes);
LCD_CreateChar(4, tmpbytes);
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 32);
lcd.createChar(5, tmpbytes);
LCD_CreateChar(5, tmpbytes);
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 40);
lcd.createChar(6, tmpbytes);
LCD_CreateChar(6, tmpbytes);
for (i = 0; i < 8; i++)
tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 48);
LCD_CreateChar(6, tmpbytes);
}
//by KD8CEC
//0 ~ 25 : 30 over : + 10
/*
void drawMeter(int needle) {
//5Char + O over
int i;
@@ -117,224 +122,79 @@ void drawMeter(int needle) {
else
lcdMeter[5] = 0x20;
}
/*
void drawMeter(int8_t needle){
int16_t best, i, s;
if (needle < 0)
return;
s = (needle * 4)/10;
for (i = 0; i < 8; i++){
if (s >= 5)
lcdMeter[i] = 1;
else if (s >= 0)
lcdMeter[i] = 2 + s;
else
lcdMeter[i] = 1;
s = s - 5;
}
if (needle >= 40)
lcdMeter[i-1] = 6;
lcdMeter[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
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);
strcpy(printBuff[linenmbr], c);
for (byte i = strlen(c); i < 16; i++) { // add white spaces until the end of the 16 characters line is reached
lcd.print(' ');
//VK2ETA meter for S.Meter, power and SWR
void drawMeter(int needle)
{
#ifdef OPTION_SKINNYBARS
//Fill buffer with growing set of bars, up to needle value
for (int i = 0; i < 6; i++) {
if (needle > i)
lcdMeter[i / 3] = byte(i + 1); //Custom characters above
else if (i == 1 || i == 4) {
lcdMeter[i / 3] = 0x20; //blank
}
}
}
void printLineF(char linenmbr, const __FlashStringHelper *c)
{
int i;
char tmpBuff[17];
PGM_P p = reinterpret_cast<PGM_P>(c);
for (i = 0; i < 17; i++){
unsigned char fChar = pgm_read_byte(p++);
tmpBuff[i] = fChar;
if (fChar == 0)
break;
}
printLine(linenmbr, tmpBuff);
}
#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++)
{
if (++lcdColumn <= LCD_MAX_COLUMN)
lcd.write(EEPROM.read(USER_CALLSIGN_DAT + i));
#else //Must be "fat" bars
//Fill buffer with growing set of bars, up to needle value
for (int i = 0; i < 6; i++) {
if (needle > i)
lcdMeter[i] = byte(i + 1); //Custom characters above
else
break;
lcdMeter[i] = 0x20; //blank
}
for (byte i = lcdColumn; i < 16; i++) //Right Padding by Space
lcd.write(' ');
if (needle > 7) {
lcdMeter[6] = byte(7); //Custom character "++"
} else if (needle > 6) {
lcdMeter[6] = 0x2B; //"+"
} else lcdMeter[6] = 0x20;
#endif //OPTION_FATBARS
}
// short cut to print to the first line
void printLine1(const char *c){
printLine(1,c);
}
// short cut to print to the first line
void printLine2(const char *c){
printLine(0,c);
}
void clearLine2()
{
printLine2("");
line2DisplayStatus = 0;
}
// short cut to print to the first line
void printLine1Clear(){
printLine(1,"");
}
// short cut to print to the first line
void printLine2Clear(){
printLine(0, "");
}
void printLine2ClearAndUpdate(){
printLine(0, "");
line2DisplayStatus = 0;
updateDisplay();
}
//012...89ABC...Z
char byteToChar(byte srcByte){
char byteToChar(byte srcByte){
if (srcByte < 10)
return 0x30 + srcByte;
else
return 'A' + srcByte - 10;
}
// this builds up the top line of the display with frequency and mode
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; //
memset(c, 0, sizeof(c));
//returns true if the button is pressed
int btnDown(void){
#ifdef EXTEND_KEY_GROUP1
if (analogRead(FBUTTON) > FUNCTION_KEY_ADC)
return 0;
else
return 1;
if (inTx){
if (isCWAutoMode == 2) {
for (i = 0; i < 4; i++)
c[3-i] = (i < autoCWSendReservCount ? byteToChar(autoCWSendReserv[i]) : ' ');
#else
if (digitalRead(FBUTTON) == HIGH)
return 0;
else
return 1;
#endif
}
//display Sending Index
c[4] = byteToChar(sendingCWTextIndex);
c[5] = '=';
}
else {
if (cwTimeout > 0)
strcpy(c, " CW:");
else
strcpy(c, " TX:");
}
}
else {
if (ritOn)
strcpy(c, "RIT ");
else {
if (cwMode == 0)
{
if (isUSB)
strcpy(c, "USB ");
else
strcpy(c, "LSB ");
}
else if (cwMode == 1)
{
strcpy(c, "CWL ");
}
else
{
strcpy(c, "CWU ");
}
}
if (vfoActive == VFO_A) // VFO A is active
strcat(c, "A:");
else
strcat(c, "B:");
}
#ifdef EXTEND_KEY_GROUP1
int getBtnStatus(void){
int readButtonValue = analogRead(FBUTTON);
//display frequency
for (int i = 15; i >= 6; i--) {
if (tmpFreq > 0) {
if (i == 12 || i == 8) c[i] = '.';
else {
c[i] = tmpFreq % 10 + 0x30;
tmpFreq /= 10;
}
}
else
c[i] = ' ';
}
//remarked by KD8CEC
//already RX/TX status display, and over index (16 x 2 LCD)
//if (inTx)
// strcat(c, " TX");
printLine(1, c);
byte diplayVFOLine = 1;
if ((displayOption1 & 0x01) == 0x01)
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.write(0x7E);
}
if (analogRead(FBUTTON) < FUNCTION_KEY_ADC)
return FKEY_PRESS;
else
{
lcd.setCursor(5,diplayVFOLine);
lcd.write(":");
readButtonValue = readButtonValue / 4;
//return FKEY_VFOCHANGE;
for (int i = 0; i < 16; i++)
if (KeyValues[i][0] <= readButtonValue && KeyValues[i][1] >= readButtonValue)
return KeyValues[i][2];
//return i;
}
/*
//now, the second line
memset(c, 0, sizeof(c));
memset(b, 0, sizeof(b));
if (inTx)
strcat(c, "TX ");
else if (ritOn)
strcpy(c, "RIT");
strcpy(c, " \xff");
drawMeter(meter_reading);
strcat(c, meter);
strcat(c, "\xff");
printLine2(c);*/
return -1;
}
#endif
int enc_prev_state = 3;

191
ubitx_20/ubitx_wspr.ino Normal file
View File

@@ -0,0 +1,191 @@
/**********************************************************************************
WSPR SENDER for uBITX by KD8CEC
Some of the code that sends WSPR referenced the code in G3ZIL.
Thanks to G3ZIL for sharing great code.
Due to the limited memory of uBITX, I have implemented at least only a few of the codes in uBITX.
Thanks for testing
Beta Tester :
-----------------------------------------------------------------------------
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/>.
**********************************************************************************/
#include <EEPROM.h>
#include "ubitx.h"
//begin of test
byte WsprToneCode[164];
unsigned long lastTime=0;
unsigned long TX_MSNB_P2; // Si5351 register MSNB_P2 PLLB for Tx
unsigned long TX_P2; // Variable values for MSNB_P2 which defines the frequencies for the data
extern int enc_read(void);
byte WsprMSGCount = 0;
#define WSPR_BAND1 401
extern uint8_t Wspr_Reg1[8]; //3, 4, 5, 6, 7
extern uint8_t Wspr_Reg2[8]; //2, 3, 4
void SendWSPRManage()
{
int knob = 0;
byte knobPosition = 0;
//char isNeedDisplayInfo = 0;
char nowSelectedIndex = 0;
char nowWsprStep = 0; //0 : select Message, 1 : select band, 2 : send
char selectedWsprMessageIndex = -1;
char selectedWsprBandIndex = -1;
unsigned long WsprTXFreq = 0;
unsigned int WsprMultiChan = 0;
//unsigned long prevFreq;
byte loopIndex;
delay_background(500, 0);
//Readed WsprMSGCount, WsprTone
while(1)
{
knob = enc_read();
if (knobPosition > 0 && knob < 0)
knobPosition--;
else if (knob > 0 && (knobPosition <= (nowWsprStep == 0 ? WsprMSGCount : WSPR_BAND_COUNT) * 10 -2))
knobPosition++;
nowSelectedIndex = knobPosition / 10;
if (nowWsprStep == 0) //select Message status
{
printLineF2(F("WSPR:"));
if (selectedWsprMessageIndex != nowSelectedIndex)
{
selectedWsprMessageIndex = nowSelectedIndex;
int wsprMessageBuffIndex = selectedWsprMessageIndex * 46;
//Display WSPR Name tag
printLineFromEEPRom(0, 6, wsprMessageBuffIndex, wsprMessageBuffIndex + 4, 1);
//Load WSPR Tonecode
//Read Tone Code
for (int i = 0; i < 41; i++)
{
byte readData = EEPROM.read(WSPR_MESSAGE1 + 5 + (wsprMessageBuffIndex) + i); //NAME TAG 5, MESSAGE 41 = 46
WsprToneCode[i * 4 + 0] = readData & 3;
WsprToneCode[i * 4 + 1] = (readData >> 2) & 3;
WsprToneCode[i * 4 + 2] = (readData >> 4) & 3;
WsprToneCode[i * 4 + 3] = (readData >> 6) & 3;
}
}
else if (btnDown())
{
nowWsprStep = 1; //Change Status to Select Band
knobPosition = 0;
nowSelectedIndex = 0;
delay_background(500, 0);
}
}
else if (nowWsprStep == 1)
{
//printLineF2(F("Select Band"));
if (selectedWsprBandIndex != nowSelectedIndex)
{
selectedWsprBandIndex = nowSelectedIndex;
int bandBuffIndex = WSPR_BAND1 + selectedWsprBandIndex * 14;
EEPROM.get(bandBuffIndex, WsprTXFreq);
EEPROM.get(bandBuffIndex + 4, WsprMultiChan);
/*
//3, 4, 5, 6, 7
Wspr_Reg1[3] = EEPROM.read(bandBuffIndex + 6);
Wspr_Reg1[4] = EEPROM.read(bandBuffIndex + 7);
Wspr_Reg1[5] = EEPROM.read(bandBuffIndex + 8);
Wspr_Reg1[6] = EEPROM.read(bandBuffIndex + 9);
Wspr_Reg1[7] = EEPROM.read(bandBuffIndex + 10);
*/
for (loopIndex = 3; loopIndex < 8; loopIndex++)
Wspr_Reg1[loopIndex] = EEPROM.read(bandBuffIndex + loopIndex + 3);
/*
Wspr_Reg2[2] = EEPROM.read(bandBuffIndex + 11);
Wspr_Reg2[3] = EEPROM.read(bandBuffIndex + 12);
Wspr_Reg2[4] = EEPROM.read(bandBuffIndex + 13);
*/
//2, 3, 4
for (loopIndex = 2; loopIndex < 5; loopIndex++)
Wspr_Reg2[loopIndex] = EEPROM.read(bandBuffIndex + loopIndex + 9);
TX_MSNB_P2 = ((unsigned long)Wspr_Reg1[5] & 0x0F) << 16 | ((unsigned long)Wspr_Reg1[6]) << 8 | Wspr_Reg1[7];
}
ltoa(WsprTXFreq, b, DEC);
if (digitalRead(PTT) == 0)
strcpy(c, "SEND:");
else
strcpy(c, "PTT->");
strcat(c, b);
printLine1(c);
if (digitalRead(PTT) == 0)
{
//printLineF1(F("Transmitting"));
//SEND WSPR
//If you need to consider the Rit and Sprite modes, uncomment them below.
//remark = To reduce the size of the program
//prevFreq = frequency;
//frequency = WsprTXFreq;
startTx(TX_CW, 0);
setTXFilters(WsprTXFreq);
//Start WSPR
Set_WSPR_Param();
digitalWrite(CW_KEY, 1);
for (int i = 0; i < 162; i++)
{ // Now this is the message loop
lastTime = millis(); // Store away the time when the last message symbol was sent
TX_P2 = TX_MSNB_P2 + WsprMultiChan * WsprToneCode[i]; // This represents the 1.46 Hz shift and is correct only for the bands specified in the array
TXSubFreq(TX_P2); // TX at the appropriate channel frequency for....
//if (btnDown())
// break;
while (millis() < lastTime + 683){} // .... 0,683 seconds
}
digitalWrite(CW_KEY, 0);
stopTx(); //call setFrequency -> recovery TX Filter
//frequency = prevFreq;
selectedWsprBandIndex = -1;
} //end of PTT Check
else if (btnDown())
{
return;
}
} //end of status check
//delay_background(50, 1);
} //end of while
}

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