mirror of
https://github.com/ole00/afterburner.git
synced 2024-11-29 06:52:55 +00:00
6beae4de9c
This change handles EXTERNAL vs AR_EXTERNAL definitions of ADC constants as defined on different Arduino platforms (Atmega vs Renesas). Also an ADC gain error is compensated for Uno R4. The compensation values are work-in-progress as I only have a single Uno R4, which might no produce typical ADC values. That means Uno R4 needs more testing reports while calibrating the VPP voltages.
360 lines
8.6 KiB
C
360 lines
8.6 KiB
C
/*
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* Variable voltage functions for Afterburner GAL project.
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*
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*/
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#include <EEPROM.h>
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// ensure mcp4131 pot uses the right pins
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#define POT_CS A3
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#define POT_CLK A4
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#define POT_DAT A5
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#define VPP A0
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#include "aftb_mcp4131.h"
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#ifndef FAIL
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#define FAIL 0
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#define OK 1
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#endif
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#define ABS(X) ((X) < 0 ? -(X) : (X));
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#define VPP_5V0 0xFF
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#define VPP_9V0 0
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#define VPP_9V5 1
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#define VPP_10V0 2
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#define VPP_10V5 3
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#define VPP_11V0 4
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#define VPP_11V5 5
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#define VPP_12V0 6
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#define VPP_12V5 7
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#define VPP_13V0 8
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#define VPP_13V5 9
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#define VPP_14V0 10
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#define VPP_14V5 11
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#define VPP_15V0 12
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#define VPP_15V5 13
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#define VPP_16V0 14
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#define VPP_16V5 15
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#define MAX_WIPER 16
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#define VPP_VERBOSE 0
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#ifdef EXTERNAL
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#define ANALOG_REF_EXTERNAL EXTERNAL
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#else
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#define ANALOG_REF_EXTERNAL AR_EXTERNAL
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#endif
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//UNO R4 Minima or Wifi (Aref internally pulled down by 130kOhm, AVR Uno R3 pulled down by 32kOhm)
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#ifdef _RENESAS_RA_
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#define AREF_IS_3V2
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#endif
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//pot wiper indices for the voltages
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uint8_t vppWiper[MAX_WIPER] = {0};
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// VPP must ramp-up to prevent voltage spikes and possibly resting arduino
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#define varVppSetMax() varVppSetVppIndex(0x40); \
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varVppSetVppIndex(0x70); \
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varVppSetVppIndex(0x7c); \
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varVppSetVppIndex(0x7e); \
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varVppSetVppIndex(0x80);
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#define varVppSetMin() varVppSetVppIndex(0x0);
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uint8_t wiperStat = 0; //enabled / disabled
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int8_t calOffset = 0; // VPP calibration offset: value 10 is 0.1V, value -10 is -0.1V
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static void varVppReadCalib(void) {
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uint8_t i;
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//calibration not found
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if (EEPROM.read(0) != 0xAF || EEPROM.read(1) != 0xCA) {
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vppWiper[0] = 0;
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Serial.println(F("No calibration data in EEPROM"));
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return;
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}
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calOffset = (int8_t) EEPROM.read(2);
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for (i = 0; i < MAX_WIPER; i++) {
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vppWiper[i] = EEPROM.read(i + 3);
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#if 0
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Serial.print(F("Calib "));
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Serial.print(i);
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Serial.print(F(":"));
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Serial.println(vppWiper[i]);
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#endif
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}
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}
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// internal use only - set the wiper value on the digital pot
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static void varVppSetVppIndex(uint8_t value) {
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uint8_t i;
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#if VPP_VERBOSE
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Serial.print(F("varSetVppIndex "));
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Serial.println(value);
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#endif
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mcp4131_write(ADDR_WIPER, value);
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#if VPP_PARANOID
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i = mcp4131_read(ADDR_WIPER);
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if (i != value) {
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Serial.print(F("Error writing POT value. Expected:"));
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Serial.print(value);
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Serial.print(F(" Actual:"));
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Serial.println(i);
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}
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#endif
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if (value == 0) {
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mcp4131_disableWiper();
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wiperStat = 0;
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} else if (wiperStat == 0) {
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mcp4131_enableWiper();
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wiperStat = 1;
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}
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}
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//use by the app code - set the variable voltage
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static void varVppSet(uint8_t value) {
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uint8_t v;
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int8_t inc;
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int8_t incMin;
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if (value == VPP_5V0 || value >= MAX_WIPER) {
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varVppSetVppIndex(0);
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return;
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}
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#if VPP_VERBOSE
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Serial.print(F("varSetVpp "));
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Serial.print(value);
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Serial.print(F(":"));
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Serial.println(vppWiper[value]);
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#endif
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//ramp up to prevent massive voltage overshoots
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v = vppWiper[value] / 2;
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v -= 2;
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inc = 16;
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incMin = 2;
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if (value > VPP_13V0) {
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incMin = 1;
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}
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while (v < vppWiper[value]) {
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varVppSetVppIndex(v);
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v+= inc + (inc / 2);
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inc -= inc / 2;
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if (inc < incMin) {
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inc = incMin;
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}
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}
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varVppSetVppIndex(vppWiper[value]);
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}
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// UNO R4/Minima - Renesas IC (significant ADC gain errors measured)
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#ifdef AREF_IS_3V2
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#define SAMPLE_CNT 16
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#define SAMPLE_DIVIDER 8
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#define SAMPLE_MULTIPLIER 25
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// SAMPLE_SHIFT moves the ADC gain error up/down
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#define SAMPLE_SHIFT -45;
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//AVR based Arduinos (no ADC gain errors measured)
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#else
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#define SAMPLE_CNT 14
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#define SAMPLE_DIVIDER 8
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#define SAMPLE_MULTIPLIER 1
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#define SAMPLE_OFFSET 5
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#endif
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static int16_t varVppMeasureVpp(int8_t printValue) {
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int8_t i = 0;
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uint16_t r1 = 0;
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int16_t r2; //correction for ADC gain error
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while (i++ < SAMPLE_CNT) {
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r1 += analogRead(VPP);
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}
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r2 = (r1 / (SAMPLE_DIVIDER * SAMPLE_MULTIPLIER));
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#ifdef SAMPLE_OFFSET
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r1+= SAMPLE_OFFSET;
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#endif
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r1 /= SAMPLE_DIVIDER;
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#ifdef SAMPLE_SHIFT
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r2 += SAMPLE_SHIFT;
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r1 += r2;
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#endif
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r1 += calOffset;
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if (printValue) {
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uint8_t a = r1%100;
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Serial.print(r1/100);
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Serial.print(F("."));
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if (a < 10) {
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Serial.print(F("0"));
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}
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#if 1
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Serial.println(a);
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#else
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//debug - display the voltage skew value in r2
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Serial.print(a);
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Serial.println(F(", "));
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Serial.println(r2);
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#endif
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}
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return r1;
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}
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// Returns 1 on Success, 0 on Failure
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static uint8_t varVppCalibrateVpp(void) {
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uint8_t vppIndex = 0;
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uint8_t i = 1;
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int16_t v = 900; //starting at 9.00 V
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int16_t r1 = 0;
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int16_t r2;
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int16_t minDif = 5000;
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Serial.print(F("VPP calib. offset: "));
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Serial.println(calOffset);
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varVppSetVppIndex(1);
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delay(300); //settle voltage
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while (1) {
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while (i <= 0x80) {
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int16_t d1,d2;
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varVppSetVppIndex(i);
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delay(50); //let the voltage settle
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#if VPP_VERBOSE
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Serial.print(i);
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Serial.print(F(") "));
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#endif
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r2 = varVppMeasureVpp(0);
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d1 = r1 - v;
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d2 = r2 - v;
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d1 = ABS(d1);
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d2 = ABS(d2);
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if (r2 <= 100) { // less than 1V ? Failure
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r1 = FAIL;
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goto ret;
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}
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if (d2 < minDif) {
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minDif = d2;
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vppWiper[vppIndex] = i;
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//check last value / voltage
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if (i == 0x80) {
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if (v >= 1620 && v <= 1670) {
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#if 1 || VPP_VERBOSE
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Serial.println(F("*Index for VPP 1650 is 128"));
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#endif
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r1 = OK;
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goto ret;
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}
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r1 = FAIL;
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goto ret;
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}
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} else {
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i--;
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minDif = 5000;
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#if 1 || VPP_VERBOSE
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Serial.print(F("*Index for VPP "));
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Serial.print(v);
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Serial.print(F(" is "));
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Serial.println(i);
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#endif
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break;
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}
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r1 = r2;
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i++;
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}
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vppIndex++;
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#if VPP_VERBOSE
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Serial.print(F("vppIndex "));
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Serial.println(vppIndex);
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#endif
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if (vppIndex >= MAX_WIPER) {
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r1 = OK;
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goto ret;
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}
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v += 50;
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}
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ret:
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varVppSet(VPP_5V0);
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return r1;
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}
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static void varVppStoreWiperCalib() {
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uint8_t i = 0;
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//sanity check
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if (vppWiper[0] == 0) {
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return;
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}
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//write Afterburner calibration header
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EEPROM.update(0, 0xAF);
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EEPROM.update(1, 0xCA);
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EEPROM.update(2, (uint8_t) calOffset);
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while (i < MAX_WIPER) {
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EEPROM.update(3 + i, vppWiper[i]);
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i++;
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}
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}
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//return 1 on success (variable VPP functionality present), 0 on failure (VPP not detected on board)
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static int8_t varVppInit(void) {
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analogReference(ANALOG_REF_EXTERNAL); //use 3V3 external reference
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wiperStat = 0; //wiper disabled
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mcp4131_init();
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if (mcp4131_detect()) {
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#if VPP_VERBOSE
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Serial.println(F("POT found"));
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#endif
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return OK;
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} else {
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#if VPP_VERBOSE
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Serial.println(F("POT not found"));
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#endif
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return FAIL;
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}
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}
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//return 1 on success (VPP calibration appears correct), 0 on failure
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static int8_t varVppCheckCalibration(void) {
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int16_t v;
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varVppReadCalib();
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if (vppWiper[0] == 0) {
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Serial.println(F("I: VPP not calibrated"));
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return FAIL;
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}
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#if 0
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// This shoots the VPP to 9V - in theory no GALs should have an issue with that voltage.
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// Also, the On switch should be turned off, preventing VPP to reach the GAL pins.
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// check actual voltage
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varVppSet(VPP_9V0);
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delay(200); //Settle voltage
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v = varVppMeasureVpp(0);
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varVppSet(VPP_5V0); //set VPP back to 5V
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// lower voltages have a good resolution, so we can have a tight voltage check bounds
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if (v < 890 || v > 910) {
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Serial.print(F("ER: VPP voltage check of 9V failed. Expected 900, measured "));
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Serial.println(v);
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return FAIL;
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}
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#endif
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return OK;
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}
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static int8_t varVppCalibrate(void) {
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if (varVppCalibrateVpp()) {
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varVppStoreWiperCalib();
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} else {
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Serial.println(F("ER: Wiper calibration failed"));
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return FAIL;
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}
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return OK;
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}
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