Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I want to define a control system block like:

class ControlSystemBlock
{
 public:
  ControlSystemBlock()
  {
   m_dbTimeStep = 0.001; // time between two consequential inputs
  }

  // this method can be called anytime,
  // but the object will assume
  // that it was called
  // after m_dbTimeStep before the last call
  void LoadNewInput(double dbInputValue);

  double GetCurrentOutput();
  // ...
 private:
  double m_dbTimeStep;
  // ...
};

The system will receive inputs, and according to these inputs and user defined transfer-function in it, its output value will change in time.

For instance, assume that I want to implement the transfer function H(s) = 1 / (s + 2). How do I do it? Is there any algorithm for that?

share|improve this question
    
Your question is not very clear to me... can you give an example of how you'd want your transfer function to be passed in? –  Vinay Pai Dec 28 '10 at 0:33

2 Answers 2

up vote 1 down vote accepted

What do you think of my code:

ControlSystemBlock.h

#ifndef CONTROLSYSTEMBLOCK_H
#define CONTROLSYSTEMBLOCK_H

#include <vector>
#include <deque>
#include "Polynomial.h"
#include "PolynomialFraction.h"

class ControlSystemBlock
{
    public:
        enum SIGNAL_TYPE
        {
            ST_DISCRETE     = 1,
            ST_CONTINUOUS   = 2
        };

        ControlSystemBlock( long double dbSamplingPeriod = 0.001);
        ControlSystemBlock( const std::vector<long double> & NominatorCoefficients,
                            const std::vector<long double> & DenominatorCoefficients,
                            SIGNAL_TYPE SignalType = SIGNAL_TYPE::ST_CONTINUOUS,
                            long double dbSamplingPeriod = 0.001);
        ControlSystemBlock( const Polynomial<long double> & NominatorPolynomial,
                            const Polynomial<long double> & DenominatorPolynomial,
                            SIGNAL_TYPE SignalType = SIGNAL_TYPE::ST_CONTINUOUS,
                            long double dbSamplingPeriod = 0.001);
        ControlSystemBlock( const PolynomialFraction<long double> & TransferFunction,
                            SIGNAL_TYPE SignalType = SIGNAL_TYPE::ST_CONTINUOUS,
                            long double dbSamplingPeriod = 0.001);

        // Sends a new input to the system block
        // Assuming that this input is sent just after m_dbSamplingPeriod seconds after the last input
        // Returns the the new output value
        long double SendInput(long double dbInput);
        long double GetOutput() const;

    protected:
        long double m_dbSamplingPeriod;
        std::deque<long double> m_InputMemory;
        std::deque<long double> m_OutputMemory;
        void SetTransferFunction(const PolynomialFraction<long double> & TransferFunction, SIGNAL_TYPE SignalType);
        PolynomialFraction<long double> m_TransferFunction;

    private:
        PolynomialFraction<long double> ContinuousTimeToDiscreteTime(const PolynomialFraction<long double> & ContinuousTimeTransferFunction);
        PolynomialFraction<long double> ContinuousTimeToDiscreteTime(const Polynomial<long double> & NominatorPolynomial,
                                                                     const Polynomial<long double> & DenominatorPolynomial);
        PolynomialFraction<long double> ContinuousTimeToDiscreteTime(const std::vector<long double> & NominatorCoefficients,
                                                                     const std::vector<long double> & DenominatorCoefficients);
        void ShiftMemoryRegisters(long double dbNewInput);
};

#endif

ControlSystemBlock.cpp

#include "ControlSystemBlock.h"

ControlSystemBlock::ControlSystemBlock( long double dbSamplingPeriod /*= 0.001*/)
{
    m_dbSamplingPeriod = dbSamplingPeriod;
    std::vector<long double> Coefficients;
    Coefficients.push_back(1.0);
    PolynomialFraction<long double> TransferFunction(Coefficients, Coefficients);
    SetTransferFunction(TransferFunction, SIGNAL_TYPE::ST_DISCRETE);
}

ControlSystemBlock::ControlSystemBlock( const std::vector<long double> & NominatorCoefficients,
                                        const std::vector<long double> & DenominatorCoefficients,
                                        SIGNAL_TYPE SignalType /*= SIGNAL_TYPE::ST_CONTINUOUS*/,
                                        long double dbSamplingPeriod /*= 0.001*/)
{
    m_dbSamplingPeriod = dbSamplingPeriod;
    PolynomialFraction<long double> TransferFunction = PolynomialFraction<long double>(NominatorCoefficients, DenominatorCoefficients);
    SetTransferFunction(TransferFunction, SignalType);
}

ControlSystemBlock::ControlSystemBlock( const Polynomial<long double> & NominatorPolynomial,
                                        const Polynomial<long double> & DenominatorPolynomial,
                                        SIGNAL_TYPE SignalType /*= SIGNAL_TYPE::ST_CONTINUOUS*/,
                                        long double dbSamplingPeriod /*= 0.001*/ )
{
    m_dbSamplingPeriod = dbSamplingPeriod;
    PolynomialFraction<long double> TransferFunction = PolynomialFraction<long double>(NominatorPolynomial, DenominatorPolynomial);
    SetTransferFunction(TransferFunction, SignalType);
}

ControlSystemBlock::ControlSystemBlock( const PolynomialFraction<long double> & TransferFunction,
                                        ControlSystemBlock::SIGNAL_TYPE SignalType /*= SIGNAL_TYPE::ST_CONTINUOUS*/,
                                        long double dbSamplingPeriod /*= 0.001*/)
{
    m_dbSamplingPeriod = dbSamplingPeriod;
    if (SignalType == SIGNAL_TYPE::ST_CONTINUOUS)
    SetTransferFunction(TransferFunction, SignalType);
}

long double ControlSystemBlock::SendInput(long double dbInput)
{
    ShiftMemoryRegisters(dbInput);
    long double dbSumX = 0.0, dbSumY = 0.0;
    for (uint64_t i=0; i<m_TransferFunction.GetNominatorDegree()+1; i++)
    {
        dbSumX += m_TransferFunction.GetNominator().GetCoefficientAt(i) * m_InputMemory.at(i);
    }
    for (uint64_t i=1; i<m_TransferFunction.GetDenominatorDegree()+1; i++)
    {
        dbSumY += m_TransferFunction.GetDenominator().GetCoefficientAt(i) * m_OutputMemory.at(i);
    }
    return m_OutputMemory.at(0) = (dbSumX - dbSumY) / m_TransferFunction.GetDenominator().GetCoefficientAt(0);
}

long double ControlSystemBlock::GetOutput() const
{
    return m_OutputMemory.at(0);
}

PolynomialFraction<long double> ControlSystemBlock::ContinuousTimeToDiscreteTime(const PolynomialFraction<long double> & ContinuousTimeTransferFunction)
{
    // Generate an "s" term in terms of "z^(-1)" terms
    std::vector<long double> nom, den;
    nom.push_back(1);
    nom.push_back(-1);
    den.push_back(1);
    den.push_back(1);
    PolynomialFraction<long double> STerm(nom, den);
    STerm *= static_cast<long double>(2) / m_dbSamplingPeriod;
    // Define nominator and denominator terms of the discrete time transfer function separately
    nom.clear();
    den.clear();
    nom.push_back(0);
    nom.push_back(1);
    PolynomialFraction<long double> NominatorOfDiscreteTimeTransferFunction(nom, den);
    PolynomialFraction<long double> DenominatorOfDiscreteTimeTransferFunction(nom, den);
    // Generate the nominator and denominator terms of the resulting discrete time transfer function
    for (uint64_t i=0; i<ContinuousTimeTransferFunction.GetNominatorDegree()+1; i++)
    {
        NominatorOfDiscreteTimeTransferFunction += STerm.GetPower(i) * ContinuousTimeTransferFunction.GetNominator().GetCoefficientAt(i);
    }
    for (uint64_t i=0; i<ContinuousTimeTransferFunction.GetDenominatorDegree()+1; i++)
    {
        NominatorOfDiscreteTimeTransferFunction += STerm.GetPower(i) * ContinuousTimeTransferFunction.GetDenominator().GetCoefficientAt(i);
    }
    return NominatorOfDiscreteTimeTransferFunction / DenominatorOfDiscreteTimeTransferFunction;
}

PolynomialFraction<long double> ControlSystemBlock::ContinuousTimeToDiscreteTime(const Polynomial<long double> & NominatorPolynomial,
                                                                                 const Polynomial<long double> & DenominatorPolynomial)
{
    PolynomialFraction<long double> ContinuousTimeTransferFunction(NominatorPolynomial, DenominatorPolynomial);
    return ContinuousTimeToDiscreteTime(ContinuousTimeTransferFunction);
}

PolynomialFraction<long double> ControlSystemBlock::ContinuousTimeToDiscreteTime(const std::vector<long double> & NominatorCoefficients,
                                                                                 const std::vector<long double> & DenominatorCoefficients)
{
    PolynomialFraction<long double> ContinuousTimeTransferFunction(NominatorCoefficients, DenominatorCoefficients);
    return ContinuousTimeToDiscreteTime(ContinuousTimeTransferFunction);
}

void ControlSystemBlock::SetTransferFunction( const PolynomialFraction<long double> & TransferFunction, SIGNAL_TYPE SignalType)
{
    if (SignalType == SIGNAL_TYPE::ST_CONTINUOUS)
    {
        m_TransferFunction = ContinuousTimeToDiscreteTime(TransferFunction);
    }
    else
    {
        m_TransferFunction = TransferFunction;
    }
    m_InputMemory.resize(m_TransferFunction.GetNominatorDegree() + 1, 0.0);
    m_OutputMemory.resize(m_TransferFunction.GetDenominatorDegree() + 1, 0.0);
}

void ControlSystemBlock::ShiftMemoryRegisters(long double dbNewInput)
{
    m_InputMemory.push_back(dbNewInput);
    m_InputMemory.pop_front();
    m_OutputMemory.push_back(0.0);
    m_OutputMemory.pop_front();
}

I have just finished it.
I going to test it soon.

share|improve this answer
    
I know that this question is a bit old... But, did this work? –  YuppieNetworking Nov 14 '11 at 9:50
    
@YuppieNetworking Yes, I have been using it for more than a year. It is working without any problem. I made some changes in the code since then. –  hkBattousai Nov 14 '11 at 17:02
    
Just one follow-up question: are your polynomial and polynomialfraction classes part of a library or are they yours? –  YuppieNetworking Nov 14 '11 at 17:21
    
@YuppieNetworking They are mine. I initially wrote them solely for this ControlSystemBlock class. There are no other non-standard dependencies except for some exception handling code. –  hkBattousai Nov 14 '11 at 18:46

Make the system accept a function (i.e. std::function in C++0x, or the equivalents in Boost) taking a double and returning a double, and use that function to do the actual calculation.

The user can then supply any arbitrary function or functor (a class overloading operator()) in order to do the transformation function you want.

Alternately, make your functions requiring the arbitrary transformation template functions and pass the functor/function pointer in by value, like the STL algorithms do.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.