forked from wirtz/BALibrary
parent
362d0928d2
commit
9b09021ef0
@ -0,0 +1,217 @@ |
||||
/*************************************************************************
|
||||
* This demo uses the BALibrary library to provide enhanced control of |
||||
* the TGA Pro board. |
||||
*
|
||||
* The latest copy of the BA Guitar library can be obtained from |
||||
* https://github.com/Blackaddr/BALibrary
|
||||
*
|
||||
* This example demonstrates teh BAAudioEffectsAnalogChorus effect. It can |
||||
* be controlled using the Blackaddr Audio "Expansion Control Board". |
||||
*
|
||||
* POT1 (left) controls the modulation rate |
||||
* POT2 (right) controls the modulation depth |
||||
* POT3 (center) controls the wet/dry mix |
||||
* SW1 will enable/bypass the audio effect. LED1 will be on when effect is enabled. |
||||
* SW2 will cycle through the 3 pre-programmed analog filters. LED2 will be on when SW2 is pressed. |
||||
*
|
||||
* Using the Serial Montitor, send 'u' and 'd' characters to increase or decrease |
||||
* the headphone volume between values of 0 and 9. |
||||
*/ |
||||
#define TGA_PRO_REVB // Set which hardware revision of the TGA Pro we're using
|
||||
#define TGA_PRO_EXPAND_REV2 // pull in the pin definitions for the Blackaddr Audio Expansion Board.
|
||||
|
||||
#include "BALibrary.h" |
||||
#include "BAEffects.h" |
||||
|
||||
using namespace BAEffects; |
||||
using namespace BALibrary; |
||||
|
||||
AudioInputI2S i2sIn; |
||||
AudioOutputI2S i2sOut; |
||||
BAAudioControlWM8731 codec; |
||||
|
||||
//#define USE_EXT // uncomment this line to use External MEM0
|
||||
|
||||
#ifdef USE_EXT |
||||
// If using external SPI memory, we will instantiate a SRAM
|
||||
// manager and create an external memory slot to use as the memory
|
||||
// for our audio delay
|
||||
ExternalSramManager externalSram; |
||||
ExtMemSlot delaySlot; // Declare an external memory slot.
|
||||
|
||||
// Instantiate the AudioEffectAnalogChorus to use external memory by
|
||||
/// passing it the delay slot.
|
||||
AudioEffectAnalogChorus analogChorus(&delaySlot); |
||||
#else |
||||
AudioEffectAnalogChorus analogChorus; // default chorus delays
|
||||
#endif |
||||
|
||||
AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
|
||||
|
||||
// Simply connect the input to the delay, and the output
|
||||
// to both i2s channels
|
||||
AudioConnection input(i2sIn,0, analogChorus,0); |
||||
AudioConnection chorusOut(analogChorus, 0, cabFilter, 0); |
||||
AudioConnection leftOut(cabFilter,0, i2sOut, 0); |
||||
AudioConnection rightOut(cabFilter,0, i2sOut, 1); |
||||
|
||||
|
||||
//////////////////////////////////////////
|
||||
// SETUP PHYSICAL CONTROLS
|
||||
// - POT1 (left) will control the rate
|
||||
// - POT2 (right) will control the depth
|
||||
// - POT3 (centre) will control the wet/dry mix.
|
||||
// - SW1 (left) will be used as a bypass control
|
||||
// - LED1 (left) will be illuminated when the effect is ON (not bypass)
|
||||
// - SW2 (right) will be used to cycle through the three built in analog filter styles available.
|
||||
// - LED2 (right) will illuminate when pressing SW2.
|
||||
//////////////////////////////////////////
|
||||
// To get the calibration values for your particular board, first run the
|
||||
// BAExpansionCalibrate.ino example and
|
||||
constexpr int potCalibMin = 1; |
||||
constexpr int potCalibMax = 1018; |
||||
constexpr bool potSwapDirection = true; |
||||
|
||||
// Create a control object using the number of switches, pots, encoders and outputs on the
|
||||
// Blackaddr Audio Expansion Board.
|
||||
BAPhysicalControls controls(BA_EXPAND_NUM_SW, BA_EXPAND_NUM_POT, BA_EXPAND_NUM_ENC, BA_EXPAND_NUM_LED); |
||||
|
||||
int loopCount = 0; |
||||
unsigned filterIndex = 0; // variable for storing which analog filter we're currently using.
|
||||
constexpr unsigned MAX_HEADPHONE_VOL = 10; |
||||
unsigned headphoneVolume = 8; // control headphone volume from 0 to 10.
|
||||
|
||||
// BAPhysicalControls returns a handle when you register a new control. We'll uses these handles when working with the controls.
|
||||
int bypassHandle, filterHandle, rateHandle, depthHandle, mixHandle, led1Handle, led2Handle; // Handles for the various controls
|
||||
|
||||
void setup() { |
||||
delay(100); // wait a bit for serial to be available
|
||||
Serial.begin(57600); // Start the serial port
|
||||
delay(100); |
||||
|
||||
// Setup the controls. The return value is the handle to use when checking for control changes, etc.
|
||||
// pushbuttons
|
||||
bypassHandle = controls.addSwitch(BA_EXPAND_SW1_PIN); // will be used for bypass control
|
||||
filterHandle = controls.addSwitch(BA_EXPAND_SW2_PIN); // will be used for stepping through filters
|
||||
// pots
|
||||
rateHandle = controls.addPot(BA_EXPAND_POT1_PIN, potCalibMin, potCalibMax, potSwapDirection); // control the amount of delay
|
||||
depthHandle = controls.addPot(BA_EXPAND_POT2_PIN, potCalibMin, potCalibMax, potSwapDirection);
|
||||
mixHandle = controls.addPot(BA_EXPAND_POT3_PIN, potCalibMin, potCalibMax, potSwapDirection);
|
||||
// leds
|
||||
led1Handle = controls.addOutput(BA_EXPAND_LED1_PIN); |
||||
led2Handle = controls.addOutput(BA_EXPAND_LED2_PIN); // will illuminate when pressing SW2
|
||||
|
||||
// Disable the audio codec first
|
||||
codec.disable(); |
||||
AudioMemory(128); |
||||
|
||||
// Enable and configure the codec
|
||||
Serial.println("Enabling codec...\n"); |
||||
codec.enable(); |
||||
codec.setHeadphoneVolume(1.0f); // Max headphone volume
|
||||
|
||||
// If using external memory request request memory from the manager
|
||||
// for the slot
|
||||
#ifdef USE_EXT |
||||
Serial.println("Using EXTERNAL memory"); |
||||
// We have to request memory be allocated to our slot.
|
||||
externalSram.requestMemory(&delaySlot, 40.0f, MemSelect::MEM0, true); // 40 ms is enough to handle the full range of the chorus delay
|
||||
#else |
||||
Serial.println("Using INTERNAL memory"); |
||||
#endif |
||||
|
||||
// Besure to enable the delay. When disabled, audio is is completely blocked by the effect
|
||||
// to minimize resource usage to nearly to nearly zero.
|
||||
analogChorus.enable();
|
||||
|
||||
// Set some default values.
|
||||
// These can be changed using the controls on the Blackaddr Audio Expansion Board
|
||||
analogChorus.bypass(false); |
||||
analogChorus.rate(0.5f); |
||||
analogChorus.mix(0.5f); |
||||
analogChorus.depth(1.0f); |
||||
|
||||
//////////////////////////////////
|
||||
// AnalogChorus filter selection //
|
||||
// These are commented out, in this example we'll use SW2 to cycle through the different filters
|
||||
//analogChorus.setFilter(AudioEffectAnalogChorus::Filter::CE2); // The default filter. Naturally bright echo (highs stay, lows fade away)
|
||||
//analogChorus.setFilter(AudioEffectAnalogChorus::Filter::WARM); // A warm filter with a smooth frequency rolloff above 2Khz
|
||||
//analogChorus.setFilter(AudioEffectAnalogChorus::Filter::DARK); // A very dark filter, with a sharp rolloff above 1Khz
|
||||
|
||||
// Guitar cabinet: Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
|
||||
cabFilter.setLowpass(0, 4500, .7071); |
||||
cabFilter.setLowpass(1, 4500, .7071); |
||||
} |
||||
|
||||
void loop() { |
||||
|
||||
float potValue; |
||||
|
||||
// Check if SW1 has been toggled (pushed)
|
||||
if (controls.isSwitchToggled(bypassHandle)) { |
||||
bool bypass = analogChorus.isBypass(); // get the current state
|
||||
bypass = !bypass; // change it
|
||||
analogChorus.bypass(bypass); // set the new state
|
||||
controls.setOutput(led1Handle, !bypass); // Set the LED when NOT bypassed
|
||||
Serial.println(String("BYPASS is ") + bypass); |
||||
} |
||||
|
||||
// Use SW2 to cycle through the filters
|
||||
controls.setOutput(led2Handle, controls.getSwitchValue(led2Handle)); |
||||
if (controls.isSwitchToggled(filterHandle)) { |
||||
filterIndex = (filterIndex + 1) % 3; // update and potentionall roll the counter 0, 1, 2, 0, 1, 2, ...
|
||||
// cast the index between 0 to 2 to the enum class AudioEffectAnalogChorus::Filter
|
||||
analogChorus.setFilter(static_cast<AudioEffectAnalogChorus::Filter>(filterIndex)); // will cycle through 0 to 2
|
||||
Serial.println(String("Filter set to ") + filterIndex); |
||||
} |
||||
|
||||
// Use POT1 (left) to control the rate setting
|
||||
if (controls.checkPotValue(rateHandle, potValue)) { |
||||
// Pot has changed
|
||||
Serial.println(String("New RATE setting: ") + potValue); |
||||
analogChorus.rate(potValue); |
||||
} |
||||
|
||||
// Use POT2 (right) to control the depth setting
|
||||
if (controls.checkPotValue(depthHandle, potValue)) { |
||||
// Pot has changed
|
||||
Serial.println(String("New DEPTH setting: ") + potValue); |
||||
analogChorus.depth(potValue); |
||||
} |
||||
|
||||
// Use POT3 (centre) to control the mix setting
|
||||
if (controls.checkPotValue(mixHandle, potValue)) { |
||||
// Pot has changed
|
||||
Serial.println(String("New MIX setting: ") + potValue); |
||||
analogChorus.mix(potValue); |
||||
} |
||||
|
||||
// Use the 'u' and 'd' keys to adjust volume across ten levels.
|
||||
if (Serial) { |
||||
if (Serial.available() > 0) { |
||||
while (Serial.available()) { |
||||
char key = Serial.read(); |
||||
if (key == 'u') {
|
||||
headphoneVolume = (headphoneVolume + 1) % MAX_HEADPHONE_VOL; |
||||
Serial.println(String("Increasing HEADPHONE volume to ") + headphoneVolume); |
||||
} |
||||
else if (key == 'd') {
|
||||
headphoneVolume = (headphoneVolume - 1) % MAX_HEADPHONE_VOL; |
||||
Serial.println(String("Decreasing HEADPHONE volume to ") + headphoneVolume); |
||||
} |
||||
codec.setHeadphoneVolume(static_cast<float>(headphoneVolume) / static_cast<float>(MAX_HEADPHONE_VOL)); |
||||
} |
||||
} |
||||
} |
||||
|
||||
// Use the loopCounter to roughly measure human timescales. Every few seconds, print the CPU usage
|
||||
// to the serial port. About 500,000 loops!
|
||||
if (loopCount % 524288 == 0) { |
||||
Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage()); |
||||
Serial.print("% "); |
||||
Serial.print(" AnalogChorus: "); Serial.print(analogChorus.processorUsage()); |
||||
Serial.println("%"); |
||||
} |
||||
loopCount++; |
||||
|
||||
} |
@ -0,0 +1,19 @@ |
||||
// To give your project a unique name, this code must be
|
||||
// placed into a .c file (its own tab). It can not be in
|
||||
// a .cpp file or your main sketch (the .ino file).
|
||||
|
||||
#include "usb_names.h" |
||||
|
||||
// Edit these lines to create your own name. The length must
|
||||
// match the number of characters in your custom name.
|
||||
|
||||
#define MIDI_NAME {'B','l','a','c','k','a','d','d','r',' ','A','u','d','i','o',' ','T','G','A',' ','P','r','o'} |
||||
#define MIDI_NAME_LEN 23 |
||||
|
||||
// Do not change this part. This exact format is required by USB.
|
||||
|
||||
struct usb_string_descriptor_struct usb_string_product_name = { |
||||
2 + MIDI_NAME_LEN * 2, |
||||
3, |
||||
MIDI_NAME |
||||
}; |
@ -0,0 +1,196 @@ |
||||
/**************************************************************************//**
|
||||
* @file |
||||
* @author Steve Lascos |
||||
* @company Blackaddr Audio |
||||
* |
||||
* AudioEffectAnalogChorus is a class for simulating a classic BBD based chorus |
||||
* like the Boss CE-2. This class works with either internal RAM, or external |
||||
* SPI RAM. The external RAM uses DMA to minimize load on the |
||||
* CPU. |
||||
* |
||||
* @copyright 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/>.
|
||||
*****************************************************************************/ |
||||
|
||||
#ifndef __BAEFFECTS_BAAUDIOEFFECTANALOGCHORUS_H |
||||
#define __BAEFFECTS_BAAUDIOEFFECTANALOGCHORUS_H |
||||
|
||||
#include <Audio.h> |
||||
#include "LibBasicFunctions.h" |
||||
|
||||
namespace BAEffects { |
||||
|
||||
/**************************************************************************//**
|
||||
* AudioEffectAnalogChorus models BBD based analog chorus. It provides controls |
||||
* for rate, depth, mix and output level. All parameters can be |
||||
* controlled by MIDI. The class supports internal memory, or external SPI |
||||
* memory by providing an ExtMemSlot. External memory access uses DMA to reduce |
||||
* process load. |
||||
*****************************************************************************/ |
||||
class AudioEffectAnalogChorus : public AudioStream { |
||||
public: |
||||
|
||||
///< List of AudioEffectAnalogChorus MIDI controllable parameters
|
||||
enum { |
||||
BYPASS = 0, ///< controls effect bypass
|
||||
RATE, ///< controls the modulate rate of the LFO
|
||||
DEPTH, ///< controls the depth of modulation of the LFO
|
||||
MIX, ///< controls the the mix of input and chorus signals
|
||||
VOLUME, ///< controls the output volume level
|
||||
NUM_CONTROLS ///< this can be used as an alias for the number of MIDI controls
|
||||
}; |
||||
|
||||
enum class Filter { |
||||
CE2 = 0, |
||||
WARM, |
||||
DARK |
||||
}; |
||||
|
||||
|
||||
/// Construct an analog chorus using internal memory. The chorus will have the
|
||||
/// default average delay.
|
||||
AudioEffectAnalogChorus(); |
||||
|
||||
/// Construct an analog chorus using external SPI via an ExtMemSlot. The chorus will have
|
||||
/// the default average delay.
|
||||
/// @param slot A pointer to the ExtMemSlot to use for the delay.
|
||||
AudioEffectAnalogChorus(BALibrary::ExtMemSlot *slot); // requires sufficiently sized pre-allocated memory
|
||||
|
||||
virtual ~AudioEffectAnalogChorus(); ///< Destructor
|
||||
|
||||
// *** PARAMETERS ***
|
||||
|
||||
/// Set the chorus average delay in milliseconds
|
||||
/// The value should be between 0.0f and 1.0f
|
||||
void setDelayConfig(float averageDelayMs, float delayRangeMs); |
||||
|
||||
/// Set the chorus average delay in number of audio samples
|
||||
/// The value should be between 0.0f and 1.0f
|
||||
void setDelayConfig(size_t averageDelayNumSamples, size_t delayRangeNumSamples); |
||||
|
||||
/// Bypass the effect.
|
||||
/// @param byp when true, bypass wil disable the effect, when false, effect is enabled.
|
||||
/// Note that audio still passes through when bypass is enabled.
|
||||
void bypass(bool byp) { m_bypass = byp; } |
||||
|
||||
/// Get if the effect is bypassed
|
||||
/// @returns true if bypassed, false if not bypassed
|
||||
bool isBypass() { return m_bypass; } |
||||
|
||||
/// Toggle the bypass effect
|
||||
void toggleBypass() { m_bypass = !m_bypass; } |
||||
|
||||
/// Set the LFO frequency where 0.0f is MIN and 1.0f is MAX
|
||||
void rate(float rate); |
||||
|
||||
/// Set the depth of LFO modulation.
|
||||
/// @param lfoDepth must be a float between 0.0f and 1.0f
|
||||
void depth(float lfoDepth) { m_lfoDepth = lfoDepth; } |
||||
|
||||
/// Set the amount of blending between dry and wet (echo) at the output.
|
||||
/// @param mix When 0.0, output is 100% dry, when 1.0, output is 100% wet. When
|
||||
/// 0.5, output is 50% Dry, 50% Wet.
|
||||
void mix(float mix) { m_mix = mix; } |
||||
|
||||
/// Set the output volume. This affect both the wet and dry signals.
|
||||
/// @details The default is 1.0.
|
||||
/// @param vol Sets the output volume between -1.0 and +1.0
|
||||
void volume(float vol) {m_volume = vol; } |
||||
|
||||
// ** ENABLE / DISABLE **
|
||||
|
||||
/// Enables audio processing. Note: when not enabled, CPU load is nearly zero.
|
||||
void enable() { m_enable = true; } |
||||
|
||||
/// Disables audio process. When disabled, CPU load is nearly zero.
|
||||
void disable() { m_enable = false; } |
||||
|
||||
// ** MIDI **
|
||||
|
||||
/// Sets whether MIDI OMNI channel is processig on or off. When on,
|
||||
/// all midi channels are used for matching CCs.
|
||||
/// @param isOmni when true, all channels are processed, when false, channel
|
||||
/// must match configured value.
|
||||
void setMidiOmni(bool isOmni) { m_isOmni = isOmni; } |
||||
|
||||
/// Configure an effect parameter to be controlled by a MIDI CC
|
||||
/// number on a particular channel.
|
||||
/// @param parameter one of the parameter names in the class enum
|
||||
/// @param midiCC the CC number from 0 to 127
|
||||
/// @param midiChannel the effect will only response to the CC on this channel
|
||||
/// when OMNI mode is off.
|
||||
void mapMidiControl(int parameter, int midiCC, int midiChannel = 0); |
||||
|
||||
/// process a MIDI Continous-Controller (CC) message
|
||||
/// @param channel the MIDI channel from 0 to 15)
|
||||
/// @param midiCC the CC number from 0 to 127
|
||||
/// @param value the CC value from 0 to 127
|
||||
void processMidi(int channel, int midiCC, int value); |
||||
|
||||
// ** FILTER COEFFICIENTS **
|
||||
|
||||
/// Set the filter coefficients to one of the presets. See AudioEffectAnalogChorus::Filter
|
||||
/// for options.
|
||||
/// @details See AudioEffectAnalogChorusFIlters.h for more details.
|
||||
/// @param filter the preset filter. E.g. AudioEffectAnalogChorus::Filter::WARM
|
||||
void setFilter(Filter filter); |
||||
|
||||
/// Override the default coefficients with your own. The number of filters stages affects how
|
||||
/// much CPU is consumed.
|
||||
/// @details The effect uses the CMSIS-DSP library for biquads which requires coefficents.
|
||||
/// be in q31 format, which means they are 32-bit signed integers representing -1.0 to slightly
|
||||
/// less than +1.0. The coeffShift parameter effectively multiplies the coefficients by 2^shift. <br>
|
||||
/// Example: If you really want +1.5, must instead use +0.75 * 2^1, thus 0.75 in q31 format is
|
||||
/// (0.75 * 2^31) = 1610612736 and coeffShift = 1.
|
||||
/// @param numStages the actual number of filter stages you want to use. Must be <= MAX_NUM_FILTER_STAGES.
|
||||
/// @param coeffs pointer to an integer array of coefficients in q31 format.
|
||||
/// @param coeffShift Coefficient scaling factor = 2^coeffShift.
|
||||
void setFilterCoeffs(int numStages, const int32_t *coeffs, int coeffShift); |
||||
|
||||
virtual void update(void); ///< update automatically called by the Teesny Audio Library
|
||||
|
||||
private: |
||||
static constexpr float m_DEFAULT_DELAY_MS = 20.0f; ///< default average delay of chorus in milliseconds
|
||||
static constexpr float m_DELAY_RANGE = 15.0f; ///< default range of delay variation in milliseconds
|
||||
static constexpr float m_LFO_MIN_RATE = 2.0f; ///< slowest possible LFO rate in milliseconds
|
||||
static constexpr float m_LFO_RANGE = 8.0f; ///< fastest possible LFO rate in milliseconds
|
||||
|
||||
audio_block_t *m_inputQueueArray[1]; |
||||
bool m_isOmni = false; |
||||
bool m_bypass = true; |
||||
bool m_enable = false; |
||||
bool m_externalMemory = false; |
||||
BALibrary::AudioDelay *m_memory = nullptr; |
||||
BALibrary::LowFrequencyOscillatorVector<float> m_lfo; |
||||
size_t m_maxDelaySamples = 0; |
||||
audio_block_t *m_previousBlock = nullptr; |
||||
audio_block_t *m_blockToRelease = nullptr; |
||||
BALibrary::IirBiQuadFilterHQ *m_iir = nullptr; |
||||
|
||||
// Controls
|
||||
int m_midiConfig[NUM_CONTROLS][2]; // stores the midi parameter mapping
|
||||
size_t m_delaySamples = 0; |
||||
float m_lfoDepth = 0.0f; |
||||
float m_mix = 0.0f; |
||||
float m_volume = 1.0f; |
||||
|
||||
void m_preProcessing(audio_block_t *out, audio_block_t *dry, audio_block_t *wet); |
||||
void m_postProcessing(audio_block_t *out, audio_block_t *dry, audio_block_t *wet); |
||||
|
||||
// Coefficients
|
||||
void m_constructFilter(void); |
||||
}; |
||||
|
||||
} |
||||
|
||||
#endif /* __BAEFFECTS_BAAUDIOEFFECTAnalogChorus_H */ |
@ -0,0 +1,83 @@ |
||||
/**************************************************************************//**
|
||||
* @file |
||||
* @author Steve Lascos |
||||
* @company Blackaddr Audio |
||||
* |
||||
* This file constains precomputed co-efficients for the AudioEffectAnalogChorus |
||||
* class. |
||||
* |
||||
* @copyright 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 <cstdint> |
||||
|
||||
namespace BAEffects { |
||||
|
||||
// The number of stages in the analog-response Biquad filter
|
||||
constexpr unsigned MAX_NUM_FILTER_STAGES = 4; |
||||
constexpr unsigned NUM_COEFFS_PER_STAGE = 5; |
||||
|
||||
// Matlab/Octave can be helpful to design a filter. Once you have the IIR filter (bz,az) coefficients
|
||||
// in the z-domain, they can be converted to second-order-sections. AudioEffectAnalogChorus is designed
|
||||
// to accept up to a maximum of an 8th order filter, broken into four, 2nd order stages.
|
||||
//
|
||||
// Second order sections can be created with:
|
||||
// [sos] = tf2sos(bz,az);
|
||||
// The results coefficents must be converted the Q31 format required by the ARM CMSIS-DSP library. This means
|
||||
// all coefficients must lie between -1.0 and +0.9999. If your (bz,az) coefficients exceed this, you must divide
|
||||
// them down by a power of 2. For example, if your largest magnitude coefficient is -3.5, you must divide by
|
||||
// 2^shift where 4=2^2 and thus shift = 2. You must then mutliply by 2^31 to get a 32-bit signed integer value
|
||||
// that represents the required Q31 coefficient.
|
||||
|
||||
// BOSS DM-3 Filters
|
||||
// b(z) = 1.0e-03 * (0.0032 0.0257 0.0900 0.1800 0.2250 0.1800 0.0900 0.0257 0.0032)
|
||||
// a(z) = 1.0000 -5.7677 14.6935 -21.3811 19.1491 -10.5202 3.2584 -0.4244 -0.0067
|
||||
constexpr unsigned CE2_NUM_STAGES = 4; |
||||
constexpr unsigned CE2_COEFF_SHIFT = 2; |
||||
constexpr int32_t CE2[5*MAX_NUM_FILTER_STAGES] = { |
||||
536870912, 988616936, 455608573, 834606945, -482959709, |
||||
536870912, 1031466345, 498793368, 965834205, -467402235, |
||||
536870912, 1105821939, 573646688, 928470657, -448083489, |
||||
2339, 5093, 2776, 302068995, 4412722 |
||||
}; |
||||
|
||||
|
||||
// Blackaddr WARM Filter
|
||||
// Butterworth, 8th order, cutoff = 2000 Hz
|
||||
// Matlab/Octave command: [bz, az] = butter(8, 2000/44100/2);
|
||||
// b(z) = 1.0e-05 * (0.0086 0.0689 0.2411 0.4821 0.6027 0.4821 0.2411 0.0689 0.0086_
|
||||
// a(z) = 1.0000 -6.5399 18.8246 -31.1340 32.3473 -21.6114 9.0643 -2.1815 0.2306
|
||||
constexpr unsigned WARM_NUM_STAGES = 4; |
||||
constexpr unsigned WARM_COEFF_SHIFT = 2; |
||||
constexpr int32_t WARM[5*MAX_NUM_FILTER_STAGES] = { |
||||
536870912,1060309346,523602393,976869875,-481046241, |
||||
536870912,1073413910,536711084,891250612,-391829326, |
||||
536870912,1087173998,550475248,835222426,-333446881, |
||||
46,92,46,807741349,-304811072 |
||||
}; |
||||
|
||||
// Blackaddr DARK Filter
|
||||
// Chebychev Type II, 8th order, stopband = 60db, cutoff = 1000 Hz
|
||||
// Matlab command: [bz, az] = cheby2(8, 60, 1000/44100/2);
|
||||
// b(z) = 0.0009 -0.0066 0.0219 -0.0423 0.0522 -0.0423 0.0219 -0.0066 0.0009
|
||||
// a(z) = 1.0000 -7.4618 24.3762 -45.5356 53.1991 -39.8032 18.6245 -4.9829 0.5836
|
||||
constexpr unsigned DARK_NUM_STAGES = 4; |
||||
constexpr unsigned DARK_COEFF_SHIFT = 1; |
||||
constexpr int32_t DARK[5*MAX_NUM_FILTER_STAGES] = { |
||||
1073741824,-2124867808,1073741824,2107780229,-1043948409, |
||||
1073741824,-2116080466,1073741824,2042553796,-979786242, |
||||
1073741824,-2077777790,1073741824,1964779896,-904264933, |
||||
957356,-1462833,957356,1896884898,-838694612 |
||||
}; |
||||
|
||||
}; |
Loading…
Reference in new issue