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control_ak4558.cpp
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control_ak4558.cpp
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/*
* HiFi Audio Codec Module support library for Teensy 3.x
*
* Copyright 2015, Michele Perla
*
*/
#include <Arduino.h>
#include "control_ak4558.h"
#include "Wire.h"
void AudioControlAK4558::initConfig(void)
{
// puts all default registers values inside an array
// this allows us to modify registers locally using annotation like follows:
//
// registers[AK4558_CTRL_1] &= ~AK4558_DIF2;
// registers[AK4558_CTRL_1] |= AK4558_DIF1 | AK4558_DIF0;
//
// after manipulation, we can write the entire register value on the CODEC
uint8_t n = 0;
Wire.requestFrom(AK4558_I2C_ADDR,10);
while(Wire.available()) {
#if AK4558_SERIAL_DEBUG > 0
Serial.print("Register ");
Serial.print(n);
Serial.print(" = ");
#endif
registers[n++] = Wire.read();
#if AK4558_SERIAL_DEBUG > 0
Serial.println(registers[n-1], BIN);
#endif
}
}
void AudioControlAK4558::readConfig(void)
{
// reads registers values
uint8_t n = 0;
uint8_t c = 0;
Wire.requestFrom(AK4558_I2C_ADDR, 10);
while(Wire.available()) {
Serial.print("Register ");
Serial.print(n++);
Serial.print(" = ");
c = Wire.read();
Serial.println(c, BIN);
}
}
bool AudioControlAK4558::write(unsigned int reg, unsigned int val)
{
Wire.beginTransmission(AK4558_I2C_ADDR);
Wire.write(reg);
Wire.write(val);
return (Wire.endTransmission(true)==0);
}
bool AudioControlAK4558::enableIn(void)
{
// ADC setup (datasheet page 74
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Enable ADC");
#endif
// ignore this, leaving default values - ADC: Set up the de-emphasis filter (Addr = 07H).
registers[AK4558_PWR_MNGT] |= AK4558_PMADR | AK4558_PMADL;
write(AK4558_PWR_MNGT, registers[AK4558_PWR_MNGT]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: PWR_MNGT set to ");
Serial.println(registers[AK4558_PWR_MNGT], BIN);
#endif
delay(300);
// Power up the ADC: PMADL = PMADR bits = “0” → “1”
// Initialization cycle of the ADC is 5200/fs @Normal mode. The SDTO pin outputs “L” during initialization.
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Enable ADC - Done");
#endif
return true;
}
bool AudioControlAK4558::enableOut(void)
{
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Enable DAC");
#endif
// DAC Output setup (datasheet page 75)
registers[AK4558_MODE_CTRL] |= AK4558_LOPS;
write(AK4558_MODE_CTRL, registers[AK4558_MODE_CTRL]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: MODE_CTRL set to ");
Serial.println(registers[AK4558_MODE_CTRL], BIN);
#endif
// Set the DAC output to power-save mode: LOPS bit “0” → “1”
// ignore this, leaving default values - DAC: Set up the digital filter mode.
// ignore this, leaving default values - Set up the digital output volume (Address = 08H, 09H).
registers[AK4558_PWR_MNGT] |= AK4558_PMDAR | AK4558_PMDAL;
write(AK4558_PWR_MNGT, registers[AK4558_PWR_MNGT]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: PWR_MNGT set to ");
Serial.println(registers[AK4558_PWR_MNGT], BIN);
#endif
delay(300);
// Power up the DAC: PMDAL = PMDAR bits = “0” → “1”
// Outputs of the LOUT and ROUT pins start rising. Rise time is 300ms (max.) when C = 1μF.
registers[AK4558_MODE_CTRL] &= ~AK4558_LOPS;
write(AK4558_MODE_CTRL, registers[AK4558_MODE_CTRL]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: MODE_CTRL set to ");
Serial.println(registers[AK4558_MODE_CTRL], BIN);
#endif
// Release power-save mode of the DAC output: LOPS bit = “1” → “0”
// Set LOPS bit to “0” after the LOUT and ROUT pins output “H”. Sound data will be output from the
// LOUT and ROUT pins after this setting.
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Enable DAC - Done");
#endif
return true;
}
bool AudioControlAK4558::enable(void)
{
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Enable device");
#endif
// Power Up and Reset
// Clock Setup (datasheet page 72)
pinMode(PIN_PDN, OUTPUT);
digitalWrite(0, LOW);
delay(1);
digitalWrite(0, HIGH);
// After Power Up: PDN pin “L” → “H”
// “L” time of 150ns or more is needed to reset the AK4558.
delay(20);
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: PDN is HIGH (device reset)");
#endif
// Control register settings become available in 10ms (min.) when LDOE pin = “H”
Wire.begin();
initConfig();
// access all registers to store locally their default values
// DIF2-0, DFS1-0 and ACKS bits must be set before MCKI, LRCK and BICK are supplied
// PMPLL = 0 (EXT Slave Mode; disables internal PLL and uses ext. clock) (by DEFAULT)
// ACKS = 0 (Manual Setting Mode; disables automatic clock selection) (by DEFAULT)
// DFS1-0 = 00 (Sampling Speed = Normal Speed Mode) (by DEFAULT)
// TDM1-0 = 00 (Time Division Multiplexing mode OFF) (by DEFAULT)
registers[AK4558_CTRL_1] &= ~AK4558_DIF2;
registers[AK4558_CTRL_1] |= AK4558_DIF1 | AK4558_DIF0;
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: CTRL_1 set to ");
Serial.println(registers[AK4558_CTRL_1], BIN);
#endif
// DIF2-1-0 = 011 ( 16 bit I2S compatible when BICK = 32fs)
registers[AK4558_CTRL_2] &= ~AK4558_MCKS1;
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: CTRL_2 set to ");
Serial.println(registers[AK4558_CTRL_2], BIN);
#endif
// MCKS1-0 = 00 (Master Clock Input Frequency Select, set 256fs for Normal Speed Mode -> 11.2896 MHz)
registers[AK4558_MODE_CTRL] &= ~AK4558_BCKO0;
// BCKO1-0 = 00 (BICK Output Frequency at Master Mode = 32fs = 1.4112 MHz)
registers[AK4558_MODE_CTRL] |= AK4558_FS1;
// Set up the sampling frequency (FS3-0 bits). The ADC must be powered-up in consideration of PLL
// lock time. (in this case (ref. table 17): Set clock to mode 5 / 44.100 KHz)
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: MODE_CTRL set to ");
Serial.println(registers[AK4558_MODE_CTRL], BIN);
#endif
// BCKO1-0 = 00 (BICK Output Frequency at Master Mode = 32fs = 1.4112 MHz)
Wire.beginTransmission(AK4558_I2C_ADDR);
Wire.write(AK4558_CTRL_1);
Wire.write(registers[AK4558_CTRL_1]);
Wire.write(registers[AK4558_CTRL_2]);
Wire.write(registers[AK4558_MODE_CTRL]);
Wire.endTransmission();
// Write configuration registers in a single write operation (datasheet page 81):
// The AK4558 can perform more than one byte write operation per sequence. After receipt of the third byte
// the AK4558 generates an acknowledge and awaits the next data. The master can transmit more than
// one byte instead of terminating the write cycle after the first data byte is transferred. After receiving each
// data packet the internal address counter is incremented by one, and the next data is automatically taken
// into the next address.
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Enable device - Done");
#endif
return true;
}
bool AudioControlAK4558::disableIn(void)
{
// ADC power-down (datasheet page 74
registers[AK4558_PWR_MNGT] &= ~AK4558_PMADR | ~AK4558_PMADL;
write(AK4558_PWR_MNGT, registers[AK4558_PWR_MNGT]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: PWR_MNGT set to ");
Serial.println(registers[AK4558_PWR_MNGT], BIN);
#endif
// Power down ADC: PMADL = PMADR bits = “1” → “0”
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Enable ADC - Done");
#endif
return true;
}
bool AudioControlAK4558::disableOut(void)
{
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Disable DAC");
#endif
// DAC Output power-down (datasheet page 75)
registers[AK4558_MODE_CTRL] |= AK4558_LOPS;
write(AK4558_MODE_CTRL, registers[AK4558_MODE_CTRL]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: MODE_CTRL set to ");
Serial.println(registers[AK4558_MODE_CTRL], BIN);
#endif
// Set the DAC output to power-save mode: LOPS bit “0” → “1”
registers[AK4558_PWR_MNGT] &= ~AK4558_PMDAR | ~AK4558_PMDAL;
write(AK4558_PWR_MNGT, registers[AK4558_PWR_MNGT]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: PWR_MNGT set to ");
Serial.println(registers[AK4558_PWR_MNGT], BIN);
#endif
delay(300);
// Power down the DAC: PMDAL = PMDAR bits = “1” → “0”
// Outputs of the LOUT and ROUT pins start falling. Rise time is 300ms (max.) when C = 1μF.
registers[AK4558_MODE_CTRL] &= ~AK4558_LOPS;
write(AK4558_MODE_CTRL, registers[AK4558_MODE_CTRL]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: MODE_CTRL set to ");
Serial.println(registers[AK4558_MODE_CTRL], BIN);
#endif
// Release power-save mode of the DAC output: LOPS bit = “1” → “0”
// Set LOPS bit to “0” after outputs of the LOUT and ROUT pins fall to “L”.
#if AK4558_SERIAL_DEBUG > 0
Serial.println("AK4558: Disable DAC - Done");
#endif
return true;
}
uint8_t AudioControlAK4558::convertVolume(float vol)
{
// Convert float (range 0.0-1.0) to unsigned char (range 0x00-0xFF)
uint8_t temp = ((uint32_t)vol)>>22;
return temp;
}
bool AudioControlAK4558::volume(float n)
{
// Set DAC output volume
uint8_t vol = convertVolume(n);
registers[AK4558_LOUT_VOL] = vol;
registers[AK4558_ROUT_VOL] = vol;
Wire.beginTransmission(AK4558_I2C_ADDR);
Wire.write(AK4558_LOUT_VOL);
Wire.write(registers[AK4558_LOUT_VOL]);
Wire.write(registers[AK4558_ROUT_VOL]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: LOUT_VOL set to ");
Serial.println(registers[AK4558_LOUT_VOL], BIN);
Serial.print("AK4558: ROUT_VOL set to ");
Serial.println(registers[AK4558_ROUT_VOL], BIN);
#endif
return (Wire.endTransmission(true)==0);
}
bool AudioControlAK4558::volumeLeft(float n)
{
// Set DAC left output volume
uint8_t vol = convertVolume(n);
registers[AK4558_LOUT_VOL] = vol;
bool ret = write(AK4558_LOUT_VOL, registers[AK4558_LOUT_VOL]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: LOUT_VOL set to ");
Serial.println(registers[AK4558_LOUT_VOL], BIN);
#endif
return ret;
}
bool AudioControlAK4558::volumeRight(float n)
{
// Set DAC right output volume
uint8_t vol = convertVolume(n);
registers[AK4558_ROUT_VOL] = vol;
bool ret = write(AK4558_ROUT_VOL, registers[AK4558_ROUT_VOL]);
#if AK4558_SERIAL_DEBUG > 0
Serial.print("AK4558: ROUT_VOL set to ");
Serial.println(registers[AK4558_ROUT_VOL], BIN);
#endif
return ret;
}