Charlie Morris, ZL2CTM

Saturday, 26 January 2019

Si5351 Quadrature Clock Output down to 3MHz

Credit to Brian Harper M1CEM and Miguel Bartié PY2OHH

Step 1. Edit si5351.h file. Change the SI5351_PLL_VCO_MIN to 380000000, i.e.,

#define SI5351_PLL_VCO_MIN 380000000

Step 2. Example code snippet:

volatile long freq = 3500000;
volatile int Even_Divisor = 0;
volatile int oldEven_Divisor = 0;

void EvenDivisor()
{
if (freq < 6850000)
{
Even_Divisor = 126;
}
if ((freq >= 6850000) && (freq < 9500000))
{
Even_Divisor = 88;
}
if ((freq >= 9500000) && (freq < 13600000))
{
Even_Divisor = 64;
}
if ((freq >= 13600000) && (freq < 17500000))
{
Even_Divisor = 44;
}
if ((freq >= 17500000) && (freq < 25000000))
{
Even_Divisor = 34;
}
if ((freq >= 25000000) && (freq < 36000000))
{
Even_Divisor = 24;
}
if ((freq >= 36000000) && (freq < 45000000)) {
Even_Divisor = 18;
}
if ((freq >= 45000000) && (freq < 60000000)) {
Even_Divisor = 14;
}
if ((freq >= 60000000) && (freq < 80000000)) {
Even_Divisor = 10;
}
if ((freq >= 80000000) && (freq < 100000000)) {
Even_Divisor = 8;
}
if ((freq >= 100000000) && (freq < 146600000)) {
Even_Divisor = 6;
}
if ((freq >= 150000000) && (freq < 220000000)) {
Even_Divisor = 4;
}
}

void SendFrequency()
{
EvenDivisor();
si5351.set_freq_manual(freq * SI5351_FREQ_MULT, Even_Divisor * freq * SI5351_FREQ_MULT, SI5351_CLK0);
si5351.set_freq_manual(freq * SI5351_FREQ_MULT, Even_Divisor * freq * SI5351_FREQ_MULT, SI5351_CLK2);
si5351.set_phase(SI5351_CLK0, 0);
si5351.set_phase(SI5351_CLK2, Even_Divisor);

if(Even_Divisor != oldEven_Divisor)
{
si5351.pll_reset(SI5351_PLLA);
oldEven_Divisor = Even_Divisor;
}
}

Monday, 14 January 2019

Homebrew Power/SWR Meter

Please see YouTube for details:

https://www.youtube.com/channel/UCSNPW3_gzuMJcX_ErBZTv2g

This is my first idea for a directional coupler. Please note that this is not suppose to be a competition or commercial grade device. My aim is to keep the costs down, but still have a functional power/SWR meter at the end.

Note also the 51 ohm (below) termination resistor is now 150 ohm.

Tandem coupler experiments. This is looking very promising with a wide frequency and power range.

Final Software:

#include <Wire.h>
#include <LiquidCrystal_I2C.h>

volatile float FwdVoltage = 0;
volatile float RevVoltage = 0;
volatile float PWR_Cal = 0;
volatile float SWR_Cal = 0;
volatile float PWR = 0;
volatile float SWR = 0;
volatile float FwdVoltageReadings[10];
volatile float FwdVoltageAverage;
volatile float RevVoltageReadings[10];
volatile float RevVoltageAverage;
volatile int FwdNumberOfLines = 0;
volatile int RevNumberOfLines = 0;
volatile int FwdNumberOfLinesToBlank = 0;
volatile int RevNumberOfLinesToBlank = 0;
volatile int AvCount = 0;

volatile double oldPWR = 0;
volatile double oldSWR = 0;

// Instantiate the Objects
LiquidCrystal_I2C lcd(0x27, 16, 2);

//Custom bar characters
const byte Bar1Array[8] = {B10000, B10000, B10000, B10000, B10000, B10000, B10000, B10000};
const byte Bar2Array[8] = {B11000, B11000, B11000, B11000, B11000, B11000, B11000, B11000};
const byte Bar3Array[8] = {B11100, B11100, B11100, B11100, B11100, B11100, B11100, B11100};
const byte Bar4Array[8] = {B11110, B11110, B11110, B11110, B11110, B11110, B11110, B11110};
const byte Bar5Array[8] = {B11111, B11111, B11111, B11111, B11111, B11111, B11111, B11111};

void setup()
{
pinMode(A0, INPUT); //Fwd power voltage pin
pinMode(A1, INPUT); //Rev power voltage pin
pinMode(A2, INPUT); //PWR cal pin
pinMode(A3, INPUT); //SWR cal pin

//analogReference(EXTERNAL);

Serial.begin(9600);
// Initialize the display
lcd.begin();
lcd.backlight();
lcd.createChar(1, Bar1Array); //Special charaters for the PWR and SWR bar display
lcd.createChar(2, Bar2Array);
lcd.createChar(3, Bar3Array);
lcd.createChar(4, Bar4Array);
lcd.createChar(5, Bar5Array);
UpdateDisplay();
}

void loop()
{
FwdVoltage = analogRead(A0);
RevVoltage = analogRead(A1);
PWR_Cal = analogRead(A2);
SWR_Cal = analogRead(A3);

FwdVoltageReadings[AvCount] = FwdVoltage; // Put fwd power reading into array
RevVoltageReadings[AvCount] = RevVoltage; // Put rev power reading into array
AvCount++;

if (AvCount == 9) // 0 to 9 = 10 bins
{
FwdVoltageAverage = 0;
RevVoltageAverage = 0;

for (int x = 0; x <= 9; x++)
FwdVoltageAverage = FwdVoltageAverage + FwdVoltageReadings[x];
FwdVoltageAverage = FwdVoltageAverage / 10; // Calc average

FwdVoltageAverage = FwdVoltageAverage - 136; // Subtract noise
FwdVoltageAverage = abs(FwdVoltageAverage); // Make absolute (remove any negative)
FwdVoltageAverage = FwdVoltageAverage * 5 / 1024; // covert into voltage
FwdVoltageAverage = FwdVoltageAverage + (PWR_Cal * 5 / 1024); // Cal to scope (no between 0 and 5)

for (int x = 0; x <= 9; x++)
RevVoltageAverage = RevVoltageAverage + RevVoltageReadings[x];

RevVoltageAverage = RevVoltageAverage / 10; // Calc average
RevVoltageAverage = RevVoltageAverage - 166; // Subtract noise
RevVoltageAverage = abs(RevVoltageAverage); // Make absolute (remove any negative)
RevVoltageAverage = RevVoltageAverage * 5 / 1024; // covert into voltage

// Lookup table for forward power
if (FwdVoltageAverage < 1.855)
PWR = 0;
else if ((FwdVoltageAverage >= 1.855) && (FwdVoltageAverage < 1.97))
PWR = 1;
else if ((FwdVoltageAverage >= 1.97) && (FwdVoltageAverage < 2.017))
PWR = 2;
else if ((FwdVoltageAverage >= 2.017) && (FwdVoltageAverage < 2.051))
PWR = 3;
else if ((FwdVoltageAverage >= 2.051) && (FwdVoltageAverage < 2.056))
PWR = 4;
else if ((FwdVoltageAverage >= 2.056) && (FwdVoltageAverage < 2.07))
PWR = 5;
else if ((FwdVoltageAverage >= 2.07) && (FwdVoltageAverage < 2.085))
PWR = 6;
else if ((FwdVoltageAverage >= 2.085) && (FwdVoltageAverage < 2.109))
PWR = 7;
else if ((FwdVoltageAverage >= 2.109) && (FwdVoltageAverage < 2.124))
PWR = 8;
else if ((FwdVoltageAverage >= 2.124) && (FwdVoltageAverage < 2.134))
PWR = 9;
else if ((FwdVoltageAverage >= 2.134) && (FwdVoltageAverage < 2.144))
PWR = 10;
else if ((FwdVoltageAverage >= 2.144) && (FwdVoltageAverage < 2.153))
PWR = 11;
else if ((FwdVoltageAverage >= 2.153) && (FwdVoltageAverage < 2.163))
PWR = 12;
else if ((FwdVoltageAverage >= 2.163) && (FwdVoltageAverage < 2.173))
PWR = 13;
else if ((FwdVoltageAverage >= 2.173) && (FwdVoltageAverage < 2.183))
PWR = 14;
else if ((FwdVoltageAverage >= 2.183) && (FwdVoltageAverage < 2.192))
PWR = 15;
else if ((FwdVoltageAverage >= 2.192) && (FwdVoltageAverage < 2.197))
PWR = 16;
else if ((FwdVoltageAverage >= 2.197) && (FwdVoltageAverage < 2.212))
PWR = 17;
else if ((FwdVoltageAverage >= 2.212) && (FwdVoltageAverage < 2.217))
PWR = 18;
else if ((FwdVoltageAverage >= 2.217) && (FwdVoltageAverage < 2.22))
PWR = 19;

// 20 - 24W
else if ((FwdVoltageAverage >= 2.220) && (FwdVoltageAverage < 2.246))
PWR = ((FwdVoltageAverage - 2.22) * 5 / .026) + 20;

// 25 - 29W
else if ((FwdVoltageAverage >= 2.246) && (FwdVoltageAverage < 2.266))
PWR = ((FwdVoltageAverage - 2.246) * 5 / .02) + 25;

// 30 - 34W
else if ((FwdVoltageAverage >= 2.266) && (FwdVoltageAverage < 2.280))
PWR = ((FwdVoltageAverage - 2.266) * 5 / .014) + 30;

// 35 - 39W
else if ((FwdVoltageAverage >= 2.280) && (FwdVoltageAverage < 2.300))
PWR = ((FwdVoltageAverage - 2.280) * 5 / .02) + 35;

// >= 40W
else if (FwdVoltage >= 2.3)
PWR = ((FwdVoltageAverage - 2.3) * 60 / .07) + 40;

if ((PWR > 0) && (PWR < 3))
FwdNumberOfLines = 1;
else
FwdNumberOfLines = PWR / 3.33; // Power bar. 100W / 30 segments = 3.33W per segment

if (PWR == 0)
SWR = 0;
else
{
SWR = (1 + sqrt(RevVoltageAverage / FwdVoltageAverage)) / (1 - sqrt(RevVoltageAverage / FwdVoltageAverage));
SWR = SWR / (SWR_Cal * 5 / 1024); // Cal to scope (no between 0 and 5)
}
RevNumberOfLines = SWR * 5; // One segment per SWR increment

AvCount = 0;
}

if ((PWR != oldPWR) || (SWR != oldSWR)) // Update display if PWR or SWR has changed
{
//SendTelemetryData();
UpdateDisplay();
oldPWR = PWR;
oldSWR = SWR;
}
}

void SendTelemetryData()
{
Serial.print("Foward Reading Average: ");
Serial.println(FwdVoltageAverage, 3);
Serial.print("Reverse Reading Average: ");
Serial.println(RevVoltageAverage, 3);
Serial.print("Power to Load: ");
Serial.println(PWR);
Serial.print("SWR: ");
Serial.println(SWR);
Serial.println("");
}

void UpdateDisplay()
{
//Display PWR
lcd.setCursor(0, 0);
lcd.print("PWR");
lcd.setCursor(3, 0);
lcd.print(" ");
lcd.setCursor(4, 0);
lcd.print(PWR, 0);

//Display SWR
lcd.setCursor(8, 0);
lcd.print("SWR");
lcd.setCursor(11, 0);
lcd.print(" ");
lcd.setCursor(12, 0);
lcd.print(SWR, 1);

//Draw PWR Bar
FwdNumberOfLinesToBlank = 29 - FwdNumberOfLines;
lcd.setCursor(0, 1);
lcd.print("P");
while (FwdNumberOfLines >= 5)
{
lcd.write(5);
FwdNumberOfLines = FwdNumberOfLines - 5;
}

if (FwdNumberOfLines == 1)
lcd.write(1);
if (FwdNumberOfLines == 2)
lcd.write(2);
if (FwdNumberOfLines == 3)
lcd.write(3);
if (FwdNumberOfLines == 4)
lcd.write(4);

while (FwdNumberOfLinesToBlank >= 5)
{
lcd.print(" ");
FwdNumberOfLinesToBlank = FwdNumberOfLinesToBlank - 5;
}

// Blank sedment before 'S'
lcd.setCursor(7, 1);
lcd.print(" ");

//Draw SWR Bar
RevNumberOfLinesToBlank = 29 - RevNumberOfLines;

lcd.setCursor(8, 1);
lcd.print("S");
while (RevNumberOfLines >= 5)
{
lcd.write(5);
RevNumberOfLines = RevNumberOfLines - 5;
}

if (RevNumberOfLines == 1)
lcd.write(1);
if (RevNumberOfLines == 2)
lcd.write(2);
if (RevNumberOfLines == 3)
lcd.write(3);
if (RevNumberOfLines == 4)
lcd.write(4);

while (RevNumberOfLinesToBlank >= 5)
{
lcd.print(" ");
RevNumberOfLinesToBlank = RevNumberOfLinesToBlank - 5;
}
}

Friday, 11 January 2019

Homebrew 2 Tone Audio Oscillator

2 Tone oscillator. Based on two Wein bridge oscillators using LM358 op amps. See YouTube for detaails:

https://youtu.be/H3f-ex2S4Xw

Wednesday, 14 November 2018

Homebrew SSB Rig based on MC1350P IF Amp

See the YouTube channel for details:

https://www.youtube.com/channel/UCSNPW3_gzuMJcX_ErBZTv2g

Audio Amplifier

Note. Original schematic had a 47uF capacitor between the two stages. That is now a 3.3uF (as above). This reduces the quiet time when changing from TX to RX.

Antenna RF Amplifier

VFO/BFO

The Si5351 outputs go to two 1k ohm trim pots. Note, this is not the correct approach. A 50 ohm pad with the appropriate attenuation should be used. The YouTube videos explain why this is incorrect. The wiper arm goes to the two ADE-1 mixers. Both trim pots are set to approx. 1/3 from min. Adjust from min to get acceptable receive audio quality.

************************************************************

This is the new code that works with Jason Mildrum's new Si5351 Etherkit library. See https://github.com/etherkit/Si5351Arduino

#include <Wire.h>

#include <SPI.h>

#include <LiquidCrystal_I2C.h>

#include <si5351.h>

const uint32_t bandStart = 7000000; // start of 40m

const uint32_t bandEnd = 7300000; // end of 40m

const uint32_t bandInit = 7100000; // where to initially set the frequency

volatile long oldfreq = 0;

volatile long currentfreq = 0;

volatile int updatedisplay = 0;

volatile uint32_t freq = bandInit ; // this is a variable (changes) - set it to the beginning of the band

volatile uint32_t radix = 1000; // how much to change the frequency by, clicking the rotary encoder will change this.

volatile uint32_t oldradix = 1;

volatile uint32_t BFO_freq = 8003000; // Crystal filter centre freq

// Rotary encoder pins and other inputs

static const int pushPin = 9;

static const int rotBPin = 2;

static const int rotAPin = 3;

// Rotary encoder variables, used by interrupt routines

volatile int rotState = 0;

volatile int rotAval = 1;

volatile int rotBval = 1;

// Instantiate the Objects

LiquidCrystal_I2C lcd(0x27, 16, 2);

Si5351 si5351;

void setup()

{

// Set up frequency and radix switches

pinMode(rotAPin, INPUT);

pinMode(rotBPin, INPUT);

pinMode(pushPin, INPUT);

// Set up pull-up resistors on inputs

digitalWrite(rotAPin, HIGH);

digitalWrite(rotBPin, HIGH);

digitalWrite(pushPin, HIGH);

// Set up interrupt pins

attachInterrupt(digitalPinToInterrupt(rotAPin), ISRrotAChange, CHANGE);

attachInterrupt(digitalPinToInterrupt(rotBPin), ISRrotBChange, CHANGE);

// Initialize the display

lcd.begin();

lcd.backlight();

UpdateDisplay();

delay(1000);

// Initialize the DDS

si5351.init(SI5351_CRYSTAL_LOAD_8PF, 0, 0);

si5351.set_correction(31830, SI5351_PLL_INPUT_XO); // Set to specific Si5351 calibration number

si5351.set_pll(SI5351_PLL_FIXED, SI5351_PLLA);

si5351.drive_strength(SI5351_CLK0, SI5351_DRIVE_8MA);

si5351.drive_strength(SI5351_CLK2, SI5351_DRIVE_8MA);

si5351.set_freq((freq * 100ULL), SI5351_CLK0);

si5351.set_freq((BFO_freq * 100ULL), SI5351_CLK2);

}

void loop()

{

currentfreq = getfreq(); // Interrupt safe method to get the current frequency

if (currentfreq != oldfreq)

{

UpdateDisplay();

SendFrequency();

oldfreq = currentfreq;

}

if (digitalRead(pushPin) == LOW)

{

delay(10);

while (digitalRead(pushPin) == LOW)

{

if (updatedisplay == 1)

{

UpdateDisplay();

updatedisplay = 0;

}

delay(50);

}

long getfreq()

{

long temp_freq;

cli();

temp_freq = freq;

sei();

return temp_freq;

}

// Interrupt routines

void ISRrotAChange()

{

if (digitalRead(rotAPin))

{

rotAval = 1;

UpdateRot();

}

else

{

rotAval = 0;

UpdateRot();

}

void ISRrotBChange()

{

if (digitalRead(rotBPin))

{

rotBval = 1;

UpdateRot();

}

else

{

rotBval = 0;

UpdateRot();

}

void UpdateRot()

{

switch (rotState)

{

case 0: // Idle state, look for direction

if (!rotBval)

rotState = 1; // CW 1

if (!rotAval)

rotState = 11; // CCW 1

break;

case 1: // CW, wait for A low while B is low

if (!rotBval)

{

if (!rotAval)

{

// either increment radixindex or freq

if (digitalRead(pushPin) == LOW)

{

updatedisplay = 1;

radix = radix / 10;

if (radix < 1)

radix = 100000;

}

else

{

freq = freq + radix;

if (freq > bandEnd)

freq = bandEnd;

}

rotState = 2; // CW 2

}

else if (rotAval)

rotState = 0; // It was just a glitch on B, go back to start

break;

case 2: // CW, wait for B high

if (rotBval)

rotState = 3; // CW 3

break;

case 3: // CW, wait for A high

if (rotAval)

rotState = 0; // back to idle (detent) state

break;

case 11: // CCW, wait for B low while A is low

if (!rotAval)

{

if (!rotBval)

{

// either decrement radixindex or freq

if (digitalRead(pushPin) == LOW)

{

updatedisplay = 1;

radix = radix * 10;

if (radix == 100000)

radix = 1;

}

else

{

freq = freq - radix;

if (freq < bandStart)

freq = bandStart;

}

rotState = 12; // CCW 2

}

else if (rotBval)

rotState = 0; // It was just a glitch on A, go back to start

break;

case 12: // CCW, wait for A high

if (rotAval)

rotState = 13; // CCW 3

break;

case 13: // CCW, wait for B high

if (rotBval)

rotState = 0; // back to idle (detent) state

break;

}

void UpdateDisplay()

{

lcd.setCursor(0, 0);

lcd.print(freq);

lcd.setCursor(0, 1);

lcd.print("ZL2CTM");

if (radix != oldradix) // stops radix display flashing/blinking on freq change

{

lcd.setCursor(9, 0);

lcd.print(" ");

lcd.setCursor(9, 0);

if (radix == 1)

lcd.print(" 1 Hz");

if (radix == 10)

lcd.print(" 10 Hz");

if (radix == 100)

lcd.print(" 100 Hz");

if (radix == 1000)

lcd.print(" 1 kHz");

if (radix == 10000)

lcd.print(" 10 kHz");

if (radix == 100000)

lcd.print("100 kHz");

oldradix = radix;

}

void SendFrequency()

{

si5351.set_freq((freq * 100ULL), SI5351_CLK0);

si5351.set_freq((BFO_freq * 100ULL), SI5351_CLK2);

}

************************************************************

BPF (note, 24g wire used, not 26g)

1st IF Amp

2nd IF Amp

Note. T1 secondary is now from Pin 4 and earth. Pin 6 is tied to earth via a 100nF cap.

Mic Amp (using an electret mic)

Note. Changed output coupling capacitor to a 1uF. Reduces short term CW on TX. A 100nF cap works well too.

Additional replay to allow the BPF and follow RF amplifier to be used for both RX (antenna amplifier) and TX (RF pre-amplifier)

RF Pre-Amp using NE592 Video Amp

Initial idea for the RF power amplifier. Based on two BLF1043 LDMOS devices.

Also using an old laptop power supply. 18.5VDC, 3A.

Please see the YouTube channel for test results!

RF Driver Amplifier.

Current layout of the final radio

AGC. Designed to provide 6-7VDC to the MC1350P.

RC phase shift oscillator for antenna/amp tuning.

Final code supporting dual band function.

#include <Wire.h>
#include <SPI.h>
#include <LiquidCrystal_I2C.h>
#include <si5351.h>

const uint32_t bandStart80 = 3500000; // start of 80m
const uint32_t bandStart40 = 7000000; // start of 40m
const uint32_t bandEnd80 = 3900000; // end of 80m
const uint32_t bandEnd40 = 7300000; // end of 40m
const uint32_t bandInit = 3690000; // where to initially set the frequency
volatile int band = 0; // 0 = 80m, 1 = 40m
volatile int oldband = 0;
volatile long oldfreq = 0;
volatile long currentfreq = 0;
volatile long freq80 = 3690000;
volatile long freq40 = 7120000;
volatile int updatedisplay = 0;
volatile long SMeterReadings[10];
volatile long SMeterAverage;
int AvCount = 0;

volatile uint32_t freq = bandInit ; // this is a variable (changes) - set it to the beginning of the band
volatile uint32_t radix = 1000; // how much to change the frequency by, clicking the rotary encoder will change this.
volatile uint32_t oldradix = 1;

volatile uint32_t BFO_freq = 9001350;

// Rotary encoder pins and other inputs
static const int pushPin = 9;
static const int rotBPin = 2;
static const int rotAPin = 3;
static const int bandSW = 4;

// Rotary encoder variables, used by interrupt routines
volatile int rotState = 0;
volatile int rotAval = 1;
volatile int rotBval = 1;

// Instantiate the Objects
LiquidCrystal_I2C lcd(0x27, 16, 2);
Si5351 si5351;

void setup()
{
// Set up frequency and radix switches
pinMode(rotAPin, INPUT);
pinMode(rotAPin, INPUT_PULLUP);
pinMode(rotBPin, INPUT);
pinMode(rotBPin, INPUT_PULLUP);
pinMode(pushPin, INPUT);
pinMode(pushPin, INPUT_PULLUP);
pinMode(bandSW, INPUT_PULLUP);
pinMode(A7, INPUT);

// Set up interrupt pins
attachInterrupt(digitalPinToInterrupt(rotAPin), ISRrotAChange, CHANGE);
attachInterrupt(digitalPinToInterrupt(rotBPin), ISRrotBChange, CHANGE);

// Initialize the display
lcd.begin();
lcd.backlight();
UpdateDisplay();
delay(1000);

// Initialize the DDS
si5351.init(SI5351_CRYSTAL_LOAD_8PF, 0, 0);
si5351.set_correction(31830, SI5351_PLL_INPUT_XO); // Set to specific Si5351 calibration number
si5351.set_pll(SI5351_PLL_FIXED, SI5351_PLLA);
si5351.drive_strength(SI5351_CLK0, SI5351_DRIVE_8MA);
si5351.drive_strength(SI5351_CLK2, SI5351_DRIVE_8MA);
si5351.set_freq((freq * 100ULL), SI5351_CLK0);
si5351.set_freq((BFO_freq * 100ULL), SI5351_CLK2);
}

void loop()
{
band = digitalRead(bandSW);
if (band != oldband) // Check if band has changed
{
if (band == 0) // Was 40m, now 80m
{
freq40 = freq; // Store 40m VFO freq
freq = freq80; // Make VFO = stored 80m freq
}
if (band == 1) // Was 80m, now 40m
{
freq80 = freq; // Store 80m VFO freq
freq = freq40; // Make VFO = stored 40m freq
}
UpdateDisplay();
oldband = band;
}

currentfreq = getfreq(); // Interrupt safe method to get the current frequency

if (currentfreq != oldfreq)
{
UpdateDisplay();
SendFrequency();
oldfreq = currentfreq;
}

if (digitalRead(pushPin) == LOW)
{
delay(10);
while (digitalRead(pushPin) == LOW)
{
if (updatedisplay == 1)
{
UpdateDisplay();
updatedisplay = 0;
}
}
delay(50);
}

SMeterReadings[AvCount] = analogRead(A7);
AvCount++;
if (AvCount == 10)
{
SMeterAverage = (SMeterReadings[0] + SMeterReadings[1] + SMeterReadings[2] + SMeterReadings[3] + SMeterReadings[4]
+ SMeterReadings[5] + SMeterReadings[6] + SMeterReadings[7] + SMeterReadings[8] + SMeterReadings[9]) / 10;
UpdateDisplay();
AvCount = 0;
}
}

long getfreq()
{
long temp_freq;
cli();
temp_freq = freq;
sei();
return temp_freq;
}

// Interrupt routines
void ISRrotAChange()
{
if (digitalRead(rotAPin))
{
rotAval = 1;
UpdateRot();
}
else
{
rotAval = 0;
UpdateRot();
}
}

void ISRrotBChange()
{
if (digitalRead(rotBPin))
{
rotBval = 1;
UpdateRot();
}
else
{
rotBval = 0;
UpdateRot();
}
}

void UpdateRot()
{
switch (rotState)
{

case 0: // Idle state, look for direction
if (!rotBval)
rotState = 1; // CW 1
if (!rotAval)
rotState = 11; // CCW 1
break;

case 1: // CW, wait for A low while B is low
if (!rotBval)
{
if (!rotAval)
{
// either increment radixindex or freq
if (digitalRead(pushPin) == LOW)
{
updatedisplay = 1;
radix = radix * 10;
if (radix > 100000)
radix = 100000;
}
else
{
freq = freq + radix;
if ((band == 0) && (freq > bandEnd80))
freq = bandEnd80;
if ((band == 1) && (freq > bandEnd40))
freq = bandEnd40;
}
rotState = 2; // CW 2
}
}
else if (rotAval)
rotState = 0; // It was just a glitch on B, go back to start
break;

case 2: // CW, wait for B high
if (rotBval)
rotState = 3; // CW 3
break;

case 3: // CW, wait for A high
if (rotAval)
rotState = 0; // back to idle (detent) state
break;

case 11: // CCW, wait for B low while A is low
if (!rotAval)
{
if (!rotBval)
{
// either decrement radixindex or freq
if (digitalRead(pushPin) == LOW)
{
updatedisplay = 1;
radix = radix / 10;
if (radix < 1)
radix = 1;
}
else
{
freq = freq - radix;
if ((band == 0) && (freq < bandStart80))
freq = bandStart80;
if ((band == 1) && (freq < bandStart40))
freq = bandStart40;
}
rotState = 12; // CCW 2
}
}
else if (rotBval)
rotState = 0; // It was just a glitch on A, go back to start
break;

case 12: // CCW, wait for A high
if (rotAval)
rotState = 13; // CCW 3
break;

case 13: // CCW, wait for B high
if (rotBval)
rotState = 0; // back to idle (detent) state
break;
}
}

void UpdateDisplay()
{
lcd.setCursor(0, 0);
lcd.setCursor(0, 0);
lcd.print(freq);
lcd.setCursor(0, 1);
lcd.print("ZL2CTM");

lcd.setCursor(11, 1);
if (SMeterAverage <= 850)
lcd.print("S3 ");
if ((SMeterAverage > 851) && (SMeterAverage <= 853))
lcd.print("S4 ");
if ((SMeterAverage > 854) && (SMeterAverage <= 864))
lcd.print("S5 ");
if ((SMeterAverage > 865) && (SMeterAverage <= 904))
lcd.print("S6 ");
if ((SMeterAverage > 905) && (SMeterAverage <= 989))
lcd.print("S7 ");
if ((SMeterAverage > 990) && (SMeterAverage <= 1010))
lcd.print("S8 ");
if (SMeterAverage > 1011)
lcd.print("S9 ");

if (radix != oldradix) // stops radix display flashing/blinking on freq change
{
lcd.setCursor(9, 0);
lcd.print(" ");
lcd.setCursor(9, 0);
if (radix == 1)
lcd.print(" 1 Hz");
if (radix == 10)
lcd.print(" 10 Hz");
if (radix == 100)
lcd.print(" 100 Hz");
if (radix == 1000)
lcd.print(" 1 kHz");
if (radix == 10000)
lcd.print(" 10 kHz");
if (radix == 100000)
lcd.print("100 kHz");
oldradix = radix;
}
}

void SendFrequency()
{
si5351.set_freq(((BFO_freq - freq) * 100ULL), SI5351_CLK0);
si5351.set_freq((BFO_freq * 100ULL), SI5351_CLK2);
}

Sunday, 11 November 2018

Portable ATU

As per the YouTube videos.

Thursday, 1 November 2018

Homebrew Antenna/Scaler Network Analyser

Final software for the antenna/SNA. It's not perfect, but works for me.

#include <UTFTGLUE.h>
#include <SPI.h>
#include <Wire.h>
#include <DDS.h>
#include <Keypad.h>

// Keypad
char keys[4][3] = {
{'1', '2', '3'},
{'4', '5', '6'},
{'7', '8', '9'},
{'*', '0', '#'}
};
byte rowPins[4] = {35, 45, 43, 39}; //connect to the row pinouts of the keypad
byte colPins[3] = {37, 33, 41}; // connect to the column pinouts of the keypad

// AD9850 pins
const int DATA = 47;
const int W_CLK = 49;
const int FQ_UD = 51;
const int RESET = 53;

// SWR bridge pins
const int fwdAntVoltageInput = A15;
const int revAntVoltageInput = A14;

// AD8307 pin
const int SNAVoltageInput = A12;

// Other constants and variables
const int NoBins = 320;
volatile long freq = 7123000;
volatile long Spotfreq = 7123000;
volatile long oldSpotfreq = 7123000;
volatile long UserLowerfreq = 8995000;
volatile long UserUpperfreq = 9005000;
volatile float fwdVoltage = 0;
volatile float revVoltage = 0;
volatile float MaxrevVoltage = 0;
volatile float OldMaxrevVoltage = 0;
volatile float MinrevVoltage = 0;
volatile float OldMinrevVoltage = 0;
volatile float Ripple = 0;
volatile float SWR = 10;
volatile float oldSWR = 0;
volatile long SWRFreq = 0;
volatile float LowestSWR = 10;
volatile int Cal = 0;
volatile long UserFreq = 0;
volatile long oldUserFreq = 0;
volatile boolean EntryComplete = false;
volatile boolean FreqEntered = false;
volatile long UserFreqArray[8] = {0};
volatile float TestArray[NoBins] = {0};
volatile float CalArray[NoBins] = {0};

// Instantiate the Objects
DDS dds(W_CLK, FQ_UD, DATA, RESET);
UTFTGLUE myGLCD(0, A2, A1, A3, A4, A0);
Keypad keypad = Keypad( makeKeymap(keys), rowPins, colPins, 4, 3 );

void setup()
{
Serial.begin(19200);

pinMode(fwdAntVoltageInput, INPUT);
pinMode(revAntVoltageInput, INPUT);
pinMode(SNAVoltageInput, INPUT);
pinMode(5, OUTPUT);
pinMode(4, OUTPUT);
pinMode(3, OUTPUT);
pinMode(2, OUTPUT);
pinMode(8, INPUT_PULLUP);
pinMode(7, INPUT_PULLUP);
pinMode(6, INPUT_PULLUP);

analogReference(INTERNAL2V56); // Built-in 2.56V reference

//Set up display
myGLCD.InitLCD();
myGLCD.clrScr();
myGLCD.setRotation(3);
DisplayMainMenu();

// Initialize the AD9850
dds.init();
dds.trim(125000000); // (Optional) trim if your xtal is not at 125MHz...
}

void loop()
{
char key = keypad.getKey();
if (key != NO_KEY)
{
switch (key) //switch used to specify which button
{
case '1':
EntryComplete = false;
DisplayAntSpotFreqMenu();
break;
case '2':
EntryComplete = false;
DisplayHFMenu();
break;
case '3':
EntryComplete = false;
DisplayHamMenu();
break;
case '4':
EntryComplete = false;
DisplayUserScanMenu();
break;
case '5':
EntryComplete = false;
DisplaySNAMenu();
break;
case '*':
EntryComplete = false;
DisplayMainMenu();
break;
default:
;
}
}
}

void DisplayMainMenu()
{
myGLCD.clrScr();
myGLCD.setTextSize(2);
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.fillRect(0, 0, 319, 30);
myGLCD.setColor(255, 255, 0);
myGLCD.setBackColor(0, 0, 255);
myGLCD.print("ZL2CTM Ant Analyser/SNA", 20, 8);
myGLCD.setColor(255, 255, 255);
myGLCD.setBackColor(0, 0, 0);
myGLCD.print("1 Spot Frequency", 30, 60);
myGLCD.print("2 HF Spectrum Scan", 30, 80);
myGLCD.print("3 Ham Band Scan", 30, 100);
myGLCD.print("4 User Scan", 30, 120);
myGLCD.print("5 Scaler Network", 30, 140);
myGLCD.print(" Analyser", 30, 160);

myGLCD.print("Select option...", 30, 200);
}

void DisplayAntSpotFreqMenu()
{
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("1 Enter frequency", 30, 20);
myGLCD.print("2 Start", 30, 40);
myGLCD.print("* Main menu", 30, 60);
myGLCD.print("Select option...", 30, 100);

myGLCD.setColor(255, 255, 0);
myGLCD.print("Freq:", 30, 160);
myGLCD.printNumI(Spotfreq, 110, 160);

while (EntryComplete == false)
{
char key = keypad.getKey();
if (key != NO_KEY)
{
switch (key) //switch used to specify which button
{
case '1':
EntryComplete = false;
Spotfreq = EnterUserFreq();
DisplayAntSpotFreqMenu();
break;
case '2':
EntryComplete = true;
AntSpotFreqScan(Spotfreq);
break;
case '*':
EntryComplete = true;
DisplayMainMenu();
break;
default:
;
}
}
}
}

void DisplayHFMenu()
{
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("1 Full HF spectrum", 30, 20);
myGLCD.print("2 2000-10000 kHz", 30, 40);
myGLCD.print("3 10000-20000 kHz", 30, 60);
myGLCD.print("4 20000-30000 kHz", 30, 80);
myGLCD.print("* Main menu", 30, 100);
myGLCD.print("Select option...", 30, 140);

while (EntryComplete == false)
{
char key = keypad.getKey();
if (key != NO_KEY)
{
switch (key) //switch used to specify which button
{
case '1':
EntryComplete = true;
SweepAnt(2000000, 30000000);
break;
case '2':
EntryComplete = true;
SweepAnt(2000000, 10000000);
break;
case '3':
EntryComplete = true;
SweepAnt(10000000, 20000000);
break;
case '4':
EntryComplete = true;
SweepAnt(20000000, 30000000);
break;
case '*':
EntryComplete = true;
DisplayMainMenu();
break;
default:
;
}
}
}
}

void DisplayHamMenu()
{
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("1 80m (3500-3900)", 30, 20);
myGLCD.print("2 40m (7000-7300)", 30, 40);
myGLCD.print("3 30m (10100-10150)", 30, 60);
myGLCD.print("4 20m (14000-14350)", 30, 80);
myGLCD.print("5 17m (18068-18168)", 30, 100);
myGLCD.print("6 15m (21000-21450)", 30, 120);
myGLCD.print("7 12m (24890-24990)", 30, 140);
myGLCD.print("8 10m (28000-29700)", 30, 160);
myGLCD.print("* Main menu", 30, 180);
myGLCD.print("Select option...", 30, 215);

while (EntryComplete == false)
{
char key = keypad.getKey();
if (key != NO_KEY)
{
switch (key) //switch used to specify which button
{
case '1':
EntryComplete = true;
SweepAnt(3500000, 3900000);
break;
case '2':
EntryComplete = true;
SweepAnt(7000000, 7300000);
break;
case '3':
EntryComplete = true;
SweepAnt(10100000, 10150000);
break;
case '4':
EntryComplete = true;
SweepAnt(14000000, 14500000);
break;
case '5':
EntryComplete = true;
SweepAnt(18068000, 18168000);
break;
case '6':
EntryComplete = true;
SweepAnt(21000000, 21450000);
break;
case '7':
EntryComplete = true;
SweepAnt(24890000, 24990000);
break;
case '8':
EntryComplete = true;
SweepAnt(28000000, 29700000);
break;
case '*':
EntryComplete = true;
DisplayMainMenu();
break;
default:
;
}
}
}
}

void DisplayUserScanMenu()
{
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("1 Enter lower freq", 30, 20);
myGLCD.print("2 Enter upper freq", 30, 40);
myGLCD.print("3 Start scan", 30, 60);
myGLCD.print("* Main menu", 30, 80);
myGLCD.print("Select option...", 30, 120);

myGLCD.setColor(255, 255, 0);
myGLCD.print("Lower:", 30, 160);
myGLCD.print("Upper:", 30, 180);
myGLCD.printNumI(UserLowerfreq, 120, 160);
myGLCD.printNumI(UserUpperfreq, 120, 180);

while (EntryComplete == false)
{
char key = keypad.getKey();
if (key != NO_KEY)
{
switch (key) //switch used to specify which button
{
case '1':
EntryComplete = false;
UserLowerfreq = EnterUserFreq();
DisplayUserScanMenu();
break;
case '2':
EntryComplete = false;
UserUpperfreq = EnterUserFreq();
DisplayUserScanMenu();
break;
case '3':
EntryComplete = true;
if (UserLowerfreq < UserUpperfreq)
SweepAnt(UserLowerfreq, UserUpperfreq);
else
SweepAnt(UserUpperfreq, UserLowerfreq);
break;
case '*':
EntryComplete = true;
DisplayMainMenu();
break;
default:
;
}
}
}
}

void DisplaySNAMenu()
{
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("1 Enter lower freq", 30, 20);
myGLCD.print("2 Enter upper freq", 30, 40);
myGLCD.print("3 Calibrate", 30, 60);
myGLCD.print("4 Single Scan", 30, 80);
myGLCD.print("5 Continuous Scan", 30, 100);
myGLCD.print("* Main menu", 30, 120);
myGLCD.print("Select option...", 30, 160);

myGLCD.setColor(255, 255, 0);
myGLCD.print("Lower:", 30, 190);
myGLCD.print("Upper:", 30, 210);
myGLCD.printNumI(UserLowerfreq, 120, 190);
myGLCD.printNumI(UserUpperfreq, 120, 210);

while (EntryComplete == false)
{
char key = keypad.getKey();
if (key != NO_KEY)
{
switch (key) //switch used to specify which button
{
case '1':
EntryComplete = false;
UserLowerfreq = EnterUserFreq();
DisplaySNAMenu();
break;
case '2':
EntryComplete = false;
UserUpperfreq = EnterUserFreq();
DisplaySNAMenu();
break;
case '3':
EntryComplete = false;
if (UserLowerfreq < UserUpperfreq)
Calibrate(UserLowerfreq, UserUpperfreq);
else
Calibrate(UserUpperfreq, UserLowerfreq);
DisplaySNAMenu();
break;
case '4':
if (Cal == 0)
{
EntryComplete = false;
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("Calibrate first", 60, 100);
delay(1500);
DisplaySNAMenu();
}
else
{
EntryComplete = true;
if (UserLowerfreq < UserUpperfreq)
SingleSweepSNA(UserLowerfreq, UserUpperfreq);
else
SingleSweepSNA(UserUpperfreq, UserLowerfreq);
}
break;
case '5':
EntryComplete = true;
if (UserLowerfreq < UserUpperfreq)
MultipleSweepSNA(UserLowerfreq, UserUpperfreq);
else
MultipleSweepSNA(UserUpperfreq, UserLowerfreq);
break;
case '*':
EntryComplete = true;
DisplayMainMenu();
break;
default:
;
}
}
}
}

long EnterUserFreq()
{
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("Enter freq between", 40, 20);
myGLCD.print("2MHz and 30MHz", 40, 40);
myGLCD.print("then press #", 40, 60);

myGLCD.setColor(105, 105, 105);
myGLCD.setTextSize(3);
myGLCD.print("8", 40, 120);
myGLCD.print("8", 65, 120);
myGLCD.print("8", 90, 120);
myGLCD.print("8", 115, 120);
myGLCD.print("8", 140, 120);
myGLCD.print("8", 165, 120);
myGLCD.print("8", 190, 120);
myGLCD.print("*", 215, 120);

FreqEntered = false;
int x = 0;
for (int y = 0; y <= 7; y++)
UserFreqArray[y] = 0;

while (FreqEntered == false)
{
char key = keypad.getKey();
if (key != NO_KEY)
{
if (key == '#')
{
FreqEntered = true;
if (x == 8)
UserFreq = ((UserFreqArray[0] * 10000000) + (UserFreqArray[1] * 1000000) + (UserFreqArray[2] * 100000) +
(UserFreqArray[3] * 10000) + (UserFreqArray[4] * 1000) + (UserFreqArray[5] * 100) + (UserFreqArray[6] * 10) + UserFreqArray[7]);
if (x == 7)
UserFreq = ((UserFreqArray[0] * 1000000) + (UserFreqArray[1] * 100000) + (UserFreqArray[2] * 10000) +
(UserFreqArray[3] * 1000) + (UserFreqArray[4] * 100) + (UserFreqArray[5] * 10) + UserFreqArray[6]);

if ((x < 7) || (UserFreq < 2000000) || (UserFreq > 30000000))
{
myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("Out of bounds", 80, 100);
UserFreq = oldUserFreq;
delay(1500);
EnterUserFreq();
}
oldUserFreq = UserFreq;
}
else
{
UserFreqArray[x] = (key - 48);
myGLCD.setColor(0, 255, 0);
myGLCD.setTextSize(3);
switch (x)
{
case 0:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
break;
case 1:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
myGLCD.printNumI(UserFreqArray[1], 65, 120);
break;
case 2:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
myGLCD.printNumI(UserFreqArray[1], 65, 120);
myGLCD.printNumI(UserFreqArray[2], 90, 120);
break;
case 3:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
myGLCD.printNumI(UserFreqArray[1], 65, 120);
myGLCD.printNumI(UserFreqArray[2], 90, 120);
myGLCD.printNumI(UserFreqArray[3], 115, 120);
break;
case 4:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
myGLCD.printNumI(UserFreqArray[1], 65, 120);
myGLCD.printNumI(UserFreqArray[2], 90, 120);
myGLCD.printNumI(UserFreqArray[3], 115, 120);
myGLCD.printNumI(UserFreqArray[4], 140, 120);
break;
case 5:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
myGLCD.printNumI(UserFreqArray[1], 65, 120);
myGLCD.printNumI(UserFreqArray[2], 90, 120);
myGLCD.printNumI(UserFreqArray[3], 115, 120);
myGLCD.printNumI(UserFreqArray[4], 140, 120);
myGLCD.printNumI(UserFreqArray[5], 165, 120);
break;
case 6:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
myGLCD.printNumI(UserFreqArray[1], 65, 120);
myGLCD.printNumI(UserFreqArray[2], 90, 120);
myGLCD.printNumI(UserFreqArray[3], 115, 120);
myGLCD.printNumI(UserFreqArray[4], 140, 120);
myGLCD.printNumI(UserFreqArray[5], 165, 120);
myGLCD.printNumI(UserFreqArray[6], 190, 120);
break;
case 7:
myGLCD.printNumI(UserFreqArray[0], 40, 120);
myGLCD.printNumI(UserFreqArray[1], 65, 120);
myGLCD.printNumI(UserFreqArray[2], 90, 120);
myGLCD.printNumI(UserFreqArray[3], 115, 120);
myGLCD.printNumI(UserFreqArray[4], 140, 120);
myGLCD.printNumI(UserFreqArray[5], 165, 120);
myGLCD.printNumI(UserFreqArray[6], 190, 120);
myGLCD.printNumI(UserFreqArray[7], 215, 120);
break;
default:
;
}
x++;
}
}
}
return UserFreq;
}

void AntSpotFreqScan(long userfrequency)
{
EntryComplete = false;

myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
dds.setFrequency(userfrequency);
delay(5);

myGLCD.setTextSize(1);
myGLCD.setColor(0, 255, 0);
myGLCD.fillRect(45, 35, 73, 40);
myGLCD.setColor(255, 255, 0);
myGLCD.fillRect(74, 35, 160, 40);
myGLCD.setColor(255, 0, 0);
myGLCD.fillRect(161, 35, 275, 40);
myGLCD.setColor(255, 255, 255);
myGLCD.drawRect(45, 34, 275, 200);

myGLCD.print("1", 45, 20);
myGLCD.print("1.5", 73, 20);
myGLCD.print("3", 160, 20);
myGLCD.print("5", 192, 20);
myGLCD.print("10", 265, 20);

myGLCD.setTextSize(2);

while (EntryComplete == false)
{
fwdVoltage = analogRead(fwdAntVoltageInput);
revVoltage = analogRead(revAntVoltageInput);

if (revVoltage >= fwdVoltage)
revVoltage = fwdVoltage - 1;

if (revVoltage < 1)
revVoltage = 1;

SWR = (fwdVoltage + revVoltage) / (fwdVoltage - revVoltage);

myGLCD.setColor(0, 0, 0);
if (oldSWR <= 1)
myGLCD.drawLine(160, 200, 46, 41);
if (oldSWR == 3)
myGLCD.drawLine(160, 200, 160, 41);
if (oldSWR >= 10)
myGLCD.drawLine(160, 200, 274, 41);
if ((oldSWR < 3) && (oldSWR > 1))
myGLCD.drawLine(160, 200, (45 + ((oldSWR - 1) * 57.5)), 41);
if ((oldSWR > 3) && (oldSWR < 10))
myGLCD.drawLine(160, 200, (160 + (oldSWR - 3) / 7 * 115), 41);

myGLCD.printNumF(oldSWR, 2, 125, 212); // Print Floating Number 2 decimal places

if (SWR <= 1.5)
myGLCD.setColor(0, 255, 0);
if ((SWR > 1.5) && (SWR <= 3))
myGLCD.setColor(255, 255, 0);
if (SWR > 3)
myGLCD.setColor(255, 0, 0);

if (SWR <= 1)
myGLCD.drawLine(160, 200, 46, 41);
if (SWR == 3)
myGLCD.drawLine(160, 200, 160, 41);
if (SWR >= 10)
myGLCD.drawLine(160, 200, 274, 41);
if ((SWR < 3) && (SWR > 1))
myGLCD.drawLine(160, 200, (45 + ((SWR - 1) * 57.5)), 41);
if ((SWR > 3) && (SWR < 10))
myGLCD.drawLine(160, 200, (160 + (SWR - 3) / 7 * 115), 41);

myGLCD.printNumF(SWR, 2, 125, 212); // Print Floating Number 2 decimal places

oldSWR = SWR;

char key = keypad.getKey();
if (key != NO_KEY) {
switch (key) //switch used to specify which button
{
case '*':
EntryComplete = true;
DisplayMainMenu();
break;
default:
;
}
}
delay(30);
}
dds.init();
dds.trim(125000000);
}

void SweepAnt(long StartFreq, long StopFreq)
{
LowestSWR = 100;
SWRFreq = 0;

myGLCD.clrScr();
myGLCD.setColor(0, 0, 255);
myGLCD.drawRect(0, 0, 319, 239);
myGLCD.setTextSize(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("Analysing...", 80, 100);

int x = 0;
for (freq = StartFreq; freq <= StopFreq; freq = freq + (((StopFreq - StartFreq) / NoBins)))
{
dds.setFrequency(freq);
delay(10); // Let DDS settle then take SWR readings

fwdVoltage = analogRead(fwdAntVoltageInput);
revVoltage = analogRead(revAntVoltageInput);

if (revVoltage >= fwdVoltage)
revVoltage = fwdVoltage - 1;

if (revVoltage < 1)
revVoltage = 1;

SWR = (fwdVoltage + revVoltage) / (fwdVoltage - revVoltage);

TestArray[x] = SWR;

if (SWR < LowestSWR)
{
LowestSWR = SWR;
SWRFreq = freq;
}
x++;
}
PlotSWR(StartFreq, StopFreq);
}

void Calibrate(long StartFreq, long StopFreq)
{
int x = 0;
float MaxCalVoltage = 0;
long freq = 0;

for (x = 0; x < NoBins; x++)
CalArray[x] = 0;
x = 0;

for (freq = StartFreq; freq <= StopFreq; freq = freq + ((StopFreq - StartFreq) / NoBins))
{
dds.setFrequency(freq);
CalArray[x] = analogRead(SNAVoltageInput);
x++;
}

for (x = 20; x < NoBins; x++) // Start at 20 to skip initial high errors
if (CalArray[x] > MaxCalVoltage) // Determine max calibration voltage
MaxCalVoltage = CalArray[x];

for (x = 0; x < NoBins; x++)
CalArray[x] = MaxCalVoltage - CalArray[x]; // Populate cal array with error offset values

Cal = 1;
}

void SingleSweepSNA(long StartFreq, long StopFreq)
{
int x = 0;
float MinTestdB = 0;
long freq = 0;

for (x = 0; x < NoBins; x++)
TestArray[x] = 0;

x = 0;

for (freq = StartFreq; freq <= StopFreq; freq = freq + ((StopFreq - StartFreq) / NoBins))
{
dds.setFrequency(freq);
TestArray[x] = analogRead(SNAVoltageInput) + CalArray[x]; // test array has corrected raw analog read voltages from 0 to 1024 (0 to 2.56 volts)
x++;
}

for (x = 0; x < NoBins; x++) // 2.56V / 25mV/dB = 102.4dB range.
TestArray[x] = 102.4 - (TestArray[x] * 102.4 / 1024); // test array now has dB levels from 0dB (2.56V = 1024) to 102dB (0V = 0)

PlotSNA();
}

void MultipleSweepSNA(long StartFreq, long StopFreq)
{
int x = 0;
float TestSNAReading = 0;

EntryComplete = false;

myGLCD.clrScr();
myGLCD.setColor(255, 255, 255);

while (EntryComplete == false)
{
for (freq = StartFreq; freq <= StopFreq; freq = freq + ((StopFreq - StartFreq) / NoBins))
{
dds.setFrequency(freq);
TestSNAReading = analogRead(SNAVoltageInput);
TestSNAReading = 102.4 - (TestSNAReading * 102.4 / 1024);
myGLCD.drawPixel(x, TestSNAReading * (240 / 102));

char key = keypad.getKey();
if (key != NO_KEY)
{
switch (key) //switch used to specify which button
{
case '*':
EntryComplete = true;
break;
default:
;
}
}
x++;
}
x = 0;
myGLCD.clrScr();
}
dds.init();
dds.trim(125000000);
DisplayMainMenu();
}

void PlotSWR(long StartFreq, long StopFreq)
{
int ax = 0;
int bx = 0;
float ay = 10;
float by = 10;

dds.init();
dds.trim(125000000);
myGLCD.clrScr();

ay = TestArray[0];
if (by > 10)
ay = 10;
ax = 0;

for (bx = 0; bx < NoBins; bx++)
{
by = TestArray[bx];
if (by > 10)
by = 10;

if (by > 3)
myGLCD.setColor(255, 0, 0); // red
else if (by <= 1.5)
myGLCD.setColor(0, 255, 0); // green
else
myGLCD.setColor(255, 255, 0); // yellow

myGLCD.drawLine(ax, 240 - (ay * 24), bx, 240 - (by * 24));
ax = bx;
ay = by;
}

myGLCD.setFont(1);
myGLCD.setColor(255, 255, 255);
myGLCD.printNumI(StartFreq / 1000, 5, 220);
myGLCD.printNumI(StopFreq / 1000, 278, 220);
myGLCD.printNumI((StopFreq + StartFreq) / 2000, 138, 220);

myGLCD.setFont(2);
myGLCD.setColor(255, 255, 255);
myGLCD.print("Freq:", 120, 20);
myGLCD.print(" SWR:", 120, 40);
myGLCD.printNumI(SWRFreq, 210, 20);
myGLCD.printNumF(LowestSWR, 2, 210, 40);
}

void PlotSNA()
{
int x = 0;
myGLCD.clrScr();
myGLCD.setColor(255, 255, 255);

for (x = 0; x < NoBins; x++)
myGLCD.drawPixel(x, TestArray[x] * (240 / 102));

myGLCD.setTextSize(1);
myGLCD.drawLine(0, 39, 10, 39);
myGLCD.print("20dB", 15, 35);
myGLCD.drawLine(0, 79, 10, 79);
myGLCD.print("40dB", 15, 75);
myGLCD.drawLine(0, 119, 10, 119);
myGLCD.print("60dB", 15, 115);
myGLCD.drawLine(0, 159, 10, 159);
myGLCD.print("80dB", 15, 155);
myGLCD.drawLine(0, 199, 10, 199);
myGLCD.print("100dB", 15, 195);

myGLCD.printNumI(UserLowerfreq / 1000, 5, 230);
myGLCD.printNumI(UserUpperfreq / 1000, 278, 230);
myGLCD.printNumI((UserUpperfreq + UserLowerfreq) / 2000, 138, 230);

}