// // FILE: X9C10X.cpp // AUTHOR: Rob Tillaart // VERSION: 0.2.2 // PURPOSE: Arduino Library for X9C10X series digital potentiometer. // URL: https://github.com/RobTillaart/X9C10X #include "X9C10X.h" // minimum pulse width CLOCK = ? us (datasheet); // digitalWrite takes enough time on UNO / AVR so clock_delay == 0 // Note that if clock pulses are long enough the data pulses are too. #ifdef __AVR__ #define X9C10X_DELAY_MICROS 0 #else #define X9C10X_DELAY_MICROS 1 #endif #define X9C10X_UP HIGH #define X9C10X_DOWN LOW #define X9C10X_MAXPOT 99 ///////////////////////////////////////////////////////// // // MINIMALISTIC BASE CLASS // X9C::X9C() { } void X9C::begin(uint8_t pulsePin, uint8_t directionPin, uint8_t selectPin) { _pulsePin = pulsePin; _directionPin = directionPin; _selectPin = selectPin; // #7 order of the initialization does matter // as it might introduce an unwanted STORE pulse. // use of pull ups might be wise. digitalWrite(_selectPin, HIGH); digitalWrite(_pulsePin, HIGH); digitalWrite(_directionPin, HIGH); pinMode(_selectPin, OUTPUT); pinMode(_pulsePin, OUTPUT); pinMode(_directionPin, OUTPUT); // wiper power up time. Page 5. delayMicroseconds(500); } bool X9C::incr() { _move(X9C10X_UP); return true; } bool X9C::decr() { _move(X9C10X_DOWN); return true; } void X9C::store() { // _pulsePin starts default HIGH digitalWrite(_selectPin, LOW); #if X9C10X_DELAY_MICROS > 0 delayMicroseconds(X9C10X_DELAY_MICROS); #endif digitalWrite(_selectPin, HIGH); delay(20); // Tcph page 5 } ///////////////////////////////////////////////////////// // // PROTECTED // void X9C::_move(uint8_t direction, uint8_t steps) { digitalWrite(_directionPin, direction); delayMicroseconds(3); // Tdi (page 5) // _pulsePin starts default HIGH digitalWrite(_selectPin, LOW); while (steps--) { digitalWrite(_pulsePin, HIGH); #if X9C10X_DELAY_MICROS > 0 delayMicroseconds(X9C10X_DELAY_MICROS); #endif digitalWrite(_pulsePin, LOW); #if X9C10X_DELAY_MICROS > 0 delayMicroseconds(X9C10X_DELAY_MICROS); #endif } // _pulsePin == LOW, (No Store, page 7) digitalWrite(_selectPin, HIGH); // reset _pulsePin to default. digitalWrite(_pulsePin, HIGH); } ///////////////////////////////////////////////////////// // // X9C10X BASE CLASS // X9C10X::X9C10X(uint32_t maxOhm) : X9C() { _maxOhm = maxOhm; } uint8_t X9C10X::setPosition(uint8_t position, bool forced) { if (position > 99) { position = 99; } // force to nearest end position first to minimize number of steps. if (forced) { if (position < 50) { _move(X9C10X_DOWN, 99); _position = 0; } else { _move(X9C10X_UP, 99); _position = 99; } } if (position > _position) { _move(X9C10X_UP, position - _position); } if (position < _position) { _move(X9C10X_DOWN, _position - position); } _position = position; return _position; } uint8_t X9C10X::getPosition() { return _position; } bool X9C10X::incr() { if (_position >= 99) return false; _position++; _move(X9C10X_UP); return true; } bool X9C10X::decr() { if (_position == 0) return false; _position--; _move(X9C10X_DOWN); return true; } uint8_t X9C10X::store() { X9C::store(); return _position; } uint8_t X9C10X::restoreInternalPosition(uint8_t position) { if (position > 99) { position = 99; } _position = position; return _position; } // rounding needed! uint32_t X9C10X::getOhm() { return (_maxOhm * _position + 49) / 99; }; uint32_t X9C10X::getMaxOhm() { return _maxOhm; }; // rounding needed! uint8_t X9C10X::Ohm2Position(uint32_t value, bool invert) { if (value > _maxOhm) return 99; uint8_t val = (99 * value + _maxOhm/2) / _maxOhm; if (invert) return 99 - val; return val; } uint16_t X9C10X::getType() { return _type; }; ///////////////////////////////////////////////////////// // // SPECIFIC DERIVED DEVICE CLASSES // X9C102::X9C102(uint32_t ohm) : X9C10X(ohm) { _type = 102; } X9C103::X9C103(uint32_t ohm) : X9C10X(ohm) { _type = 103; } X9C104::X9C104(uint32_t ohm) : X9C10X(ohm) { _type = 104; } X9C503::X9C503(uint32_t ohm) : X9C10X(ohm) { _type = 503; } // -- END OF FILE --