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sdrangel/sdrbase/dsp/agc.h

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/*
* kissagc.h
*
* Created on: May 12, 2015
* Author: f4exb
*/
#ifndef INCLUDE_GPL_DSP_AGC_H_
#define INCLUDE_GPL_DSP_AGC_H_
#include "movingaverage.h"
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#include "util/movingaverage.h"
#include "export.h"
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class SDRBASE_API AGC
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{
public:
AGC(int historySize, double R);
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virtual ~AGC();
void resize(int historySize, double R);
void setOrder(double R) { m_R = R; }
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Real getValue();
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Real getAverage();
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virtual void feed(Complex& ci) = 0;
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protected:
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double m_u0; //!< AGC factor
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double m_R; //!< ordered magnitude
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MovingAverage<double> m_moving_average; //!< Averaging engine. The stack length conditions the smoothness of AGC.
int m_historySize; //!< Averaging length (attack)
int m_count; //!< Samples counter
};
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class SDRBASE_API MagAGC : public AGC
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{
public:
MagAGC(int historySize, double R, double threshold);
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virtual ~MagAGC();
void setSquared(bool squared) { m_squared = squared; }
void resize(int historySize, int stepLength, Real R);
void setOrder(double R);
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virtual void feed(Complex& ci);
double feedAndGetValue(const Complex& ci);
double getMagSq() const { return m_magsq; }
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void setThreshold(double threshold) { m_threshold = threshold; }
void setThresholdEnable(bool enable);
void setGate(int gate) { m_gate = gate; m_gateCounter = 0; m_count = 0; }
void setStepDownDelay(int stepDownDelay) { m_stepDownDelay = stepDownDelay; m_gateCounter = 0; m_count = 0; }
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void setClamping(bool clamping) { m_clamping = clamping; }
void setClampMax(double clampMax) { m_clampMax = clampMax; }
int getStepDownDelay() const { return m_stepDownDelay; }
float getStepValue() const;
void setHardLimiting(bool hardLimiting) { m_hardLimiting = hardLimiting; }
private:
bool m_squared; //!< use squared magnitude (power) to compute AGC value
double m_magsq; //!< current squared magnitude (power)
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double m_threshold; //!< squelch on magsq average
bool m_thresholdEnable; //!< enable squelch on power threshold
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int m_gate; //!< power threshold gate in number of samples
int m_stepLength; //!< transition step length in number of samples
double m_stepDelta; //!< transition step unit by sample
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int m_stepUpCounter; //!< step up transition samples counter
int m_stepDownCounter; //!< step down transition samples counter
int m_gateCounter; //!< threshold gate samples counter
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int m_stepDownDelay; //!< delay in samples before cutoff (release)
bool m_clamping; //!< clamping active
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double m_R2; //!< square of ordered magnitude
double m_clampMax; //!< maximum to clamp to as power value
bool m_hardLimiting; //!< hard limit multiplier so that resulting sample magnitude does not exceed 1.0
double hardLimiter(double multiplier, double magsq);
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};
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template<uint32_t AvgSize>
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class SimpleAGC
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{
public:
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SimpleAGC(Real initial, Real cutoff=0, Real clip=0) :
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m_cutoff(cutoff),
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m_clip(clip),
m_moving_average(AvgSize, initial)
{
}
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void resize(Real initial, Real cutoff=0, Real clip=0)
{
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m_cutoff = cutoff;
m_clip = clip;
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m_moving_average.resize(AvgSize, initial);
}
void resizeNew(uint32_t newSize, Real initial, Real cutoff=0, Real clip=0)
{
m_cutoff = cutoff;
m_clip = clip;
m_moving_average.resize(newSize, initial);
}
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void fill(double value)
{
m_moving_average.fill(value);
}
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Real getValue()
{
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if ((Real) m_moving_average.average() > m_clip) {
return (Real) m_moving_average.average();
} else {
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return m_clip;
}
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}
void feed(Real value)
{
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if (value > m_cutoff) {
m_moving_average.feed(value);
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}
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}
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private:
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Real m_cutoff; // consider samples only above this level
Real m_clip; // never go below this level
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MovingAverage<double> m_moving_average; // Averaging engine. The stack length conditions the smoothness of AGC.
//MovingAverageUtil<Real, double, AvgSize> m_moving_average;
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};
#endif /* INCLUDE_GPL_DSP_AGC_H_ */