Exemple #1
0
        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            if (_previousInputs.IsReady)
            {
                var a = input.Close - input.Open;
                var b = _previousInputs[0].Close - _previousInputs[0].Open;
                var c = _previousInputs[1].Close - _previousInputs[1].Open;
                var d = _previousInputs[2].Close - _previousInputs[2].Open;
                var e = input.High - input.Low;
                var f = _previousInputs[0].High - _previousInputs[0].Low;
                var g = _previousInputs[1].High - _previousInputs[1].Low;
                var h = _previousInputs[2].High - _previousInputs[2].Low;
                CloseBand.Update(input.Time, (a + 2 * (b + c) + d) / 6);
                RangeBand.Update(input.Time, (e + 2 * (f + g) + h) / 6);

                if (CloseBand.IsReady && RangeBand.IsReady && RangeBand != 0m)
                {
                    _previousInputs.Add(input);
                    var rvi = CloseBand / RangeBand;
                    Signal?.Update(input.Time, rvi); // Checks for null before updating.
                    return(rvi);
                }
            }

            _previousInputs.Add(input);
            return(0m);
        }
Exemple #2
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        /// <summary>
        /// Computes the next value for the indicator
        ///
        ///
        /// </summary>
        /// <param name="window"></param>
        /// <param name="input"></param>
        /// <returns></returns>
        /// <remarks>
        /// From Ehlers page 15 equation 2.7 and Easy Language code on page 34 figure 4.2
        /// His formula is changed slightly because he uses _cycle[1] in the second line of the high
        /// pass filter.  Easy Language creates the newest reading in the indicator before the formula is evaluated,
        ///    so that _cycle[1] refers to "yesterday" (in daily parlance) and _cycle is the newly created
        ///    reading with an implicit index of [0].
        /// On the other had, Lean's Add method adds the result of the formula to the underlying list
        ///    after it has been evaluated, so that "yesterday's" value in the formula is _cycle[0] not _cycle[1] as Ehlers says.
        ///After the Add _cycle[0] is the latest value and yesterday's value is _cycle[1]
        ///
        /// _smooth, on the other hand, has already been added, so I can use _smooth[1] to refer to "yesterday's" value
        ///Following is the high pass filter used for the instanteous trend
        /// I create the intermediate hfp variable for clarity in the code.
        ///</remarks>
        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            // for convenience
            var time = input.Time;

            if (barcount > 2)
            {
                _smooth.Add(idp(time, (window[0].Value + 2 * window[1].Value + window[2].Value / 6)));

                if (barcount < _period)
                {
                    _cycle.Add(idp(time, (window[0].Value - 2 * window[1].Value + window[2].Value) / 4));
                }
                else
                {
                    // Calc the high pass filter _cycle value
                    var hfp = (1 - a / 2) * (1 - a / 2) * (_smooth[0].Value - 2 * _smooth[1].Value + _smooth[2].Value)
                              + 2 * (1 - a) * _cycle[0].Value - (1 - a) * (1 - a) * _cycle[1].Value;
                    _cycle.Add(idp(time, hfp));
                }
            }
            else
            {
                _smooth.Add(idp(time, window[0].Value));
                _cycle.Add(idp(time, 0));
            }
            barcount++;
            return(_cycle[0].Value);
        }
Exemple #3
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        /// <summary>
        /// A Fisher Transform of Prices
        /// </summary>
        /// <param name="name">string - the name of the indicator</param>
        /// <param name="period">The number of periods for the indicator</param>
        public FisherTransform(string name, int period)
            : base(name, period)
        {
            // Initialize the local variables
            _maxHigh = new Maximum("MaxHigh", period);
            _minLow  = new Minimum("MinLow", period);
            value1   = new RollingWindow <IndicatorDataPoint>(period);

            // add two minimum values to the value1 to get things started
            value1.Add(new IndicatorDataPoint(DateTime.MinValue, .0001m));
            value1.Add(new IndicatorDataPoint(DateTime.MinValue, .0001m));
        }
        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IndicatorDataPoint input)
        {
            _price.Add((double)input.Price);

            if (_price.Samples == 1)
            {
                _price.Add(_price[0]);
                _price.Add(_price[0]);
            }

            double signal = _a0 * _c0 * (_b0 * _price[0] + _b1 * _price[1] + _b2 * _price[2]) + _a0 * (_a1 * _filt[0] + _a2 * _filt[1]);

            _filt.Add(signal);

            return((decimal)signal);
        }
Exemple #5
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        protected override decimal ComputeNextValue(IndicatorDataPoint input)
        {
            double realPart = 0;
            double imagPart = 0;

            _prices.Add(input);

            if (!_prices.IsReady)
            {
                return(LeadDirection);
            }

            for (int i = 0; i < _period; i++)
            {
                double temp = (double)_prices[i].Value;
                realPart = realPart + temp * Math.Cos(2 * Math.PI * i / _period);
                imagPart = imagPart + temp * Math.Sin(2 * Math.PI * i / _period);
            }

            double phase1 = Math.Abs(realPart) > 0.001 ? Math.Atan(imagPart / realPart) : Math.PI / 2 * Math.Sign(imagPart);
            double phase2 = realPart < 0 ? phase1 + Math.PI : phase1;
            double phase  = phase2 < 0 ? phase2 + 2 * Math.PI : phase2 > 2 * Math.PI ? phase2 - 2 * Math.PI : phase2;

            _sine.Update(input.EndTime, (decimal)Math.Cos(phase));
            _lead.Update(input.EndTime, (decimal)Math.Cos(phase + Math.PI / 4));

            _direction = _lead > _sine ? Direction.Up : _lead < _sine ? Direction.Down : _direction;

            return(LeadDirection);
        }
Exemple #6
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        protected override decimal ComputeNextValue(TradeBar input)
        {
            _previousBars.Add(input);

            if (_previousBars.IsReady)
            {
                if (_previousBars[2].High > _previousBars[0].High &&
                    _previousBars[2].High > _previousBars[1].High &&
                    _previousBars[2].High > _previousBars[3].High &&
                    _previousBars[2].High > _previousBars[4].High)
                {
                    _barryUp = input.High;
                }

                if (_previousBars[2].Low > _previousBars[0].Low &&
                    _previousBars[2].Low > _previousBars[1].Low &&
                    _previousBars[2].Low > _previousBars[3].Low &&
                    _previousBars[2].Low > _previousBars[4].Low)
                {
                    _barryDown = input.Low;
                }
            }

            return(MidPoint);
        }
Exemple #7
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        /// <summary>
        /// Computes the next value for this indicator from the given state.
        ///
        /// As this indicator is receiving data points from two different symbols,
        /// it's going to compute the next value when the amount of data points
        /// of each of them is the same. Otherwise, it will return the last beta
        /// value computed
        /// </summary>
        /// <param name="input">The input value of this indicator on this time step.
        /// It can be either from the target or the reference symbol</param>
        /// <returns>The beta value of the target used in relation with the reference</returns>
        protected override decimal ComputeNextValue(TradeBar input)
        {
            var inputSymbol = input.Symbol;

            if (inputSymbol == _targetSymbol)
            {
                _targetDataPoints.Add(input.Close);
            }
            else if (inputSymbol == _referenceSymbol)
            {
                _referenceDataPoints.Add(input.Close);
            }
            else
            {
                throw new Exception("The given symbol was not target or reference symbol");
            }

            if (_targetDataPoints.Samples == _referenceDataPoints.Samples && _referenceDataPoints.Count > 1)
            {
                _targetReturns.Add(GetNewReturn(_targetDataPoints));
                _referenceReturns.Add(GetNewReturn(_referenceDataPoints));

                ComputeBeta();
            }
            return(_beta);
        }
Exemple #8
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        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            _adx.Update(input);
            _adxHistory.Add(_adx);

            return((_adx + _adxHistory[Math.Min(_adxHistory.Count - 1, _period - 1)]) / 2);
        }
Exemple #9
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        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            _bars.Add(input);

            if (!_bars.IsReady)
            {
                return(0m);
            }

            double beta  = Math.Cos(2 * Math.PI / _period);
            double gamma = (1 / Math.Cos(4 * Math.PI * (double)_delta / _period));
            double alpha = gamma - Math.Sqrt(Math.Pow(gamma, 2) - 1);
            double p0    = (double)(_bars[0].High + _bars[0].Low) / 2;
            double p2    = (double)(_bars[2].High + _bars[2].Low) / 2;
            double bp    = _bps.IsReady ? 0.5 * (1 - alpha) * (p0 - p2) + beta * (1 + alpha) * _bps[0] - alpha * _bps[1] : 0.5 * (1 - alpha) * (p0 - p2);

            _bps.Add(bp);
            _bpMA.Update(input.Time, (decimal)bp);

            if (!_bps.IsReady)
            {
                return(0m);
            }

            double peak   = _bps[1] > _bps[0] && _bps[1] > _bps[2] ? _bps[1] : (double)_peak.Current.Value;
            double valley = _bps[1] < _bps[0] && _bps[1] < _bps[2] ? _bps[1] : (double)_valley.Current.Value;

            _peak.Update(input.Time, (decimal)peak);
            _valley.Update(input.Time, (decimal)valley);
            _peakMA.Update(input.Time, (decimal)peak);
            _valleyMA.Update(input.Time, (decimal)valley);

            return(_bpMA.IsReady ? _bpMA : 0m);
        }
Exemple #10
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 /// <summary>
 ///     Computes the next value for this indicator from the given state.
 /// </summary>
 /// <param name="window">The window of data held in this indicator</param>
 /// <param name="input">The input value to this indicator on this time step</param>        /// <returns></returns>
 /// <remarks>
 /// The Hull moving average is a series of nested weighted moving averages.
 /// Using the LWMA custom function for calculating weighted moving averages,
 /// the Hull moving average can be calculated following the steps.
 ///
 ///1.Calculate the n periodweighted moving average of a series "=WMA(price for n periods)"
 ///2.Calculate the n/2 period weighted moving average of a series"=WMA(price for n/2 periods)". Round n/2 to the nearest whole number
 ///3.Create a time series with 2*WMA from Step 2 - WMA from Step 1
 ///4.The HMA is the WMA of the series in Step 3. "=WMA(Step 3 outputs fo k period)"
 /// </remarks>
 protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
 {
     _longWma.Update(input);
     _shortWma.Update(input);
     _smooth.Add(new IndicatorDataPoint(input.Time, 2 * _shortWma.Current.Value - _longWma.Current.Value));
     _result.Update(new IndicatorDataPoint(input.Time, _smooth[0].Value));
     return(_result.Current.Value);
 }
Exemple #11
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 /// <summary>
 /// Invokes NewPivotPointFormed event
 /// </summary>
 private void OnNewPivotPointFormed(PivotPoint pivotPoint)
 {
     if (pivotPoint != null)
     {
         _windowPivotPoints.Add(pivotPoint);
         NewPivotPointFormed?.Invoke(this, new PivotPointsEventArgs(pivotPoint));
     }
 }
Exemple #12
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        /// <summary>
        /// Calculates the next value for the decycle
        /// </summary>
        /// <param name="window">the window for this indicator</param>
        /// <param name="input">the latest price to input into the trend</param>
        /// <returns>the computed value</returns>
        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            // for convenience
            DateTime time = input.Time;

            _price.Add(input);

            if (!_price.IsReady)
            {
                _decycle.Add(input);
            }
            else
            {
                decimal decycle = alpha / 2 * (_price[0] + _price[1]) + (1 - alpha) * _decycle[1];
                _decycle.Add(idp(time, decycle));
            }

            return(_decycle[0]);
        }
        /// <summary>
        /// Computes the average value
        /// </summary>
        /// <param name="input">The data for the calculation</param>
        /// <returns>The average value</returns>
        protected override decimal ComputeNextValue(TradeBar input)
        {
            var price = (double)(input.High + input.Low) / 2;

            _high.Add((double)input.High);
            _low.Add((double)input.Low);

            // our first data point just return identity
            if (!_high.IsReady)
            {
                _filt = price;
            }
            double n1;
            double n2;
            double n3;
            double hh;
            double ll;
            double dimen = 0;
            double alpha;

            n3 = (_high.Max() - _low.Min()) / _n;

            hh = _high.Take(_n / 2).Max();
            ll = _low.Take(_n / 2).Min();

            n1 = (hh - ll) / (_n / 2);

            if (_high.IsReady)
            {
                hh = _high.Skip(_n / 2).Take(_n / 2).Max();
                ll = _low.Skip(_n / 2).Take(_n / 2).Min();
            }

            n2 = (hh - ll) / (_n / 2);

            if (n1 > 0 && n2 > 0 && n3 > 0)
            {
                dimen = (Math.Log(n1 + n2) - Math.Log(n3)) / Math.Log(2);
            }
            ;

            alpha = Math.Exp(_w * (dimen - 1));
            if (alpha < .01)
            {
                alpha = .01;
            }
            if (alpha > 1)
            {
                alpha = 1;
            }

            _filt = alpha * price + (1 - alpha) * _filt;

            return((decimal)_filt);
        }
Exemple #14
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        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            _adx.Update(input);

            if (_adx.IsReady)
            {
                _adxHistory.Add(_adx);
            }

            return(IsReady ? (_adx + _adxHistory[_period - 1]) / 2 : 50m);
        }
Exemple #15
0
        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            ADX.Update(input);

            if (ADX.IsReady)
            {
                _adxHistory.Add(ADX.Current.Value);
            }

            return(IsReady ? (ADX.Current.Value + _adxHistory[_period - 1]) / 2 : 50m);
        }
        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="window"></param>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>
        /// A new value for this indicator
        /// </returns>
        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            if (window.Count >= 3)
            {
                _multipliedDiffWindow.Add((window[0] - window[1]) * (window[1] - window[2]));
            }

            // Estimate the indicator if less than 50% of observation are zero. Avoid division by
            // zero and estimations with few real observations in case of forward filled data.
            if (IsReady && _multipliedDiffWindow.Count(obs => obs == 0) < 0.5 * _multipliedDiffWindow.Count)
            {
                var mc  = _multipliedDiffWindow.Count(obs => obs > 0);
                var mRc = _multipliedDiffWindow.Count(obs => obs < 0);
                return(100m * mc / (mc + mRc));
            }
            return(50m);
        }
        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(TradeBar input)
        {
            // Save the bar for summing
            Bars.Add(input);

            // check if it is not ready add a 0 to the RviWindow
            if (!Bars.IsReady)
            {
                RviWindow.Add(new IndicatorDataPoint(input.EndTime, 0.0m));
            }
            else
            {
                // Bars have been added, so Bars[0] is the current value of the input


                // Filter the Close - Open with a four-bar symetical FIR filter before the terms are summed.
                var v1 = ((Bars[0].Close - Bars[0].Open) + 2 * (Bars[1].Close - Bars[1].Open) +
                          2 * (Bars[2].Close - Bars[3].Open) + (Bars[3].Close - Bars[3].Open) / 6);
                value1.Add(new IndicatorDataPoint(input.EndTime, v1));

                // Filter the High - Low with a four-bar symetical FIR filter before the terms are summed.
                var v2 = ((Bars[0].High - Bars[0].Low) + 2 * (Bars[1].High - Bars[1].Low) +
                          2 * (Bars[2].High - Bars[3].Low) + (Bars[3].High - Bars[3].Low) / 6);
                value2.Add(new IndicatorDataPoint(input.EndTime, v2));

                // The numerator and denominator are summed independently
                decimal num   = value1.Sum(point => point.Value);
                decimal denom = value2.Sum(point => point.Value);

                try
                {
                    // The RVI is the ratio of the numerator to the denominator.  Since
                    //  they are lagged by the same amount, due to the filtering,
                    //  the lag is removed by taking the ratio.
                    RviWindow.Add(new IndicatorDataPoint(input.EndTime, num / denom));
                }
                catch (DivideByZeroException zex)
                {
                    throw new Exception(zex.Message + zex.StackTrace);
                }
            }
            return(RviWindow[0].Value);
        }
Exemple #18
0
        /// <summary>
        /// Computes the average value
        /// </summary>
        /// <param name="input">The data for the calculation</param>
        /// <returns>The average value</returns>
        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            var price = (input.High + input.Low) / 2;

            _high.Add((double)input.High);
            _low.Add((double)input.Low);

            // our first data point just return identity
            if (_high.Samples <= _high.Size)
            {
                return(price);
            }

            var hh = _high.Take(_n / 2).Max();
            var ll = _low.Take(_n / 2).Min();
            var n1 = (hh - ll) / (_n / 2);

            hh = _high.Skip(_n / 2).Take(_n / 2).Max();
            ll = _low.Skip(_n / 2).Take(_n / 2).Min();

            var n2 = (hh - ll) / (_n / 2);
            var n3 = (_high.Max() - _low.Min()) / _n;

            double dimen = 0;

            if (n1 + n2 > 0 && n3 > 0)
            {
                dimen = Math.Log((n1 + n2) / n3) / Math.Log(2);
            }

            var alpha = (decimal)Math.Exp(_w * (dimen - 1));

            if (alpha < .01m)
            {
                alpha = .01m;
            }
            if (alpha > 1)
            {
                alpha = 1;
            }

            return(alpha * price + (1 - alpha) * Current.Value);
        }
Exemple #19
0
        protected override decimal ComputeNextValue(TradeBar input)
        {
            _fractal.Add(input);

            if (!_fractal.IsReady)
            {
                return(MidPoint);
            }

            if (_fractal.IndexOfMax((bar, index) => bar.High) == _fractalMidIndex)
            {
                _barryUp = input.High;
            }

            if (_fractal.IndexOfMin((bar, index) => bar.Low) == _fractalMidIndex)
            {
                _barryDown = input.Low;
            }

            return(MidPoint);
        }
        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            var stop = 0;
            var src  = input.Value;

            if (src == Src.FirstOrDefault())
            {
                return(xEma);
            }
            Src.Add(src);

            if (Src.IsReady)
            {
                //PFE = sqrt(pow(close - close[Length], 2) + 100)
                var s1    = Src.Skip(1).FirstOrDefault();
                var sL    = Src.LastOrDefault();
                var perfL = src - sL;
                PFE = Math.Sqrt((double)(perfL * perfL) + 100);

                //C2C = sum(sqrt(pow((close - close[1]), 2) + 1), Length)
                var perf1 = src - s1;
                var tosum = Math.Sqrt((double)(perf1 * perf1) + 1);
                C2C.Add(tosum);

                //xFracEff = iff(close - close[Length] > 0,  round((PFE / C2C) * 100) , round(-(PFE / C2C) * 100))
                double c2csum   = 0;
                double xFracEff = 0;
                if (C2C.IsReady)
                {
                    c2csum   = C2C.Sum();
                    xFracEff = (perfL > 0) ? Math.Round(PFE / c2csum * 100)  : Math.Round(-PFE / c2csum * 100);
                    xEma.Update(input.Time, (decimal)xFracEff);
                }
                if (xEma.IsReady)
                {
                    return(xEma);           //Math.Min(Math.Max(xEma, -100), 100);
                }
            }
            return(0);
        }
Exemple #21
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        /// <summary>
        /// Computes the next value for this indicator from the given state.
        /// </summary>
        /// <param name="input">The input value to this indicator on this time step</param>
        /// <returns>A a value for this indicator</returns>
        protected override decimal ComputeNextValue(IndicatorDataPoint input)
        {
            _rollingData.Add(input.Value);
            if (_rollingData.Count < 3)
            {
                return(0m);
            }

            var previousPoint  = _rollingData[1];
            var previousPoint2 = _rollingData[2];

            var logPoint = 0.0;

            if (previousPoint2 != 0)
            {
                logPoint = Math.Log((double)(previousPoint / previousPoint2));
            }

            _standardDeviation.Update(input.Time, (decimal)logPoint);

            if (!_rollingData.IsReady)
            {
                return(0m);
            }
            if (!_standardDeviation.IsReady)
            {
                return(0m);
            }

            var m = _standardDeviation.Current.Value * previousPoint;

            if (m == 0)
            {
                return(0);
            }

            var spikeValue = (input.Value - previousPoint) / m;

            return(spikeValue);
        }
Exemple #22
0
        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            _windowHighs.Add(input);
            _windowLows.Add(input);

            PivotPoint highPoint = null, lowPoint = null;

            if (_windowHighs.IsReady)
            {
                highPoint = FindNextHighPivotPoint(_windowHighs, _surroundingBarsCountForHighPoint);
            }

            if (_windowLows.IsReady)
            {
                lowPoint = FindNextLowPivotPoint(_windowLows, _surroundingBarsCountForLowPoint);
            }

            OnNewPivotPointFormed(highPoint);
            OnNewPivotPointFormed(lowPoint);

            return(ConvertToComputedValue(highPoint, lowPoint));
        }
Exemple #23
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        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="window"></param>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>
        /// A new value for this indicator
        /// </returns>
        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            int     Mc        = 0;
            int     MRc       = 0;
            decimal momersion = 50m;

            if (window.Count >= 3)
            {
                _multipliedDiffWindow.Add((window[0] - window[1]) * (window[1] - window[2]));
            }

            // Estimate the indicator if less than 50% of observation are zero. Avoid division by
            // zero and estimations with few real observations in case of forward filled data.
            if (this.IsReady &&
                _multipliedDiffWindow.Count(obs => obs == 0) < 0.5 * _multipliedDiffWindow.Count)
            {
                Mc        = _multipliedDiffWindow.Count(obs => obs > 0);
                MRc       = _multipliedDiffWindow.Count(obs => obs < 0);
                momersion = 100m * Mc / (Mc + MRc);
            }
            return(momersion);
        }
        /// <summary>
        /// Computes the next value for this indicator from the given state.
        /// </summary>
        /// <param name="window">The window of data held in this indicator</param>
        /// <param name="input">The input value to this indicator on this time step</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            decimal         dominantCycle;
            List <double>   Correlations;
            Vector <double> DTF;

            hpf.Update(input);
            sSmoother.Update(hpf.Current);
            sSmootherWindow.Add((double)sSmoother.Current.Value);

            if (!this.IsReady)
            {
                dominantCycle = 0m;
            }
            else
            {
                Correlations  = EstimateAutocorrelations();
                DTF           = EstimateDFT(Correlations);
                dominantCycle = EstimateDominantCycle(DTF);
            }
            return(dominantCycle);
        }
        /// <summary>
        /// Forecasts the series of the fitted model one point ahead.
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IndicatorDataPoint input)
        {
            _rollingData.Add((double)input.Value);
            if (_rollingData.IsReady)
            {
                var arrayData = _rollingData.ToArray();
                arrayData = _diffOrder > 0 ? DifferenceSeries(_diffOrder, arrayData, out _diffHeads) : arrayData;
                TwoStepFit(arrayData);
                double summants = 0;
                if (_arOrder > 0)
                {
                    for (var i = 0; i < _arOrder; i++) // AR Parameters
                    {
                        summants += ArParameters[i] * arrayData[i];
                    }
                }

                if (_maOrder > 0)
                {
                    for (var i = 0; i < _maOrder; i++) // MA Parameters
                    {
                        summants += MaParameters[i] * _residuals[_maOrder + i + 1];
                    }
                }

                summants += Intercept; // By default equals 0

                if (_diffOrder > 0)
                {
                    var dataCast = arrayData.ToList();
                    dataCast.Insert(0, summants);                                                // Prepends
                    summants = InverseDifferencedSeries(dataCast.ToArray(), _diffHeads).First(); // Returns disintegrated series
                }

                return((decimal)summants);
            }

            return(0m);
        }
Exemple #26
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        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            // AroonUp.Update(input.Time, input.High);
            // AroonDown.Update(input.Time, input.Low);
            var src = input.Value;

            Src.Add(src);

            if (Src.IsReady)
            {
                var it1 = (It.IsReady) ? It[0] :  ((src + 2 * Src[1] + Src[2]) / 4);
                var it2 = (It.IsReady) ? It[1] :  ((src + 2 * Src[1] + Src[2]) / 4);

                var it = (_alpha - ((_alpha * _alpha) / 4)) * src
                         + 0.5m * _alpha * _alpha * Src[1]
                         - (_alpha - 0.75m * _alpha * _alpha) * Src[2]
                         + 2 * (1 - _alpha) * it1
                         - (1 - _alpha) * (1 - _alpha) * it2;
                Lag = 2 * it - it2;
                It.Add(it);
                InstantaneousTrend = it;
            }
            return(Lag - InstantaneousTrend);
        }
Exemple #27
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        /// <summary>
        /// Computes the next value in the transform.
        /// value1 is a function used to normalize price withing the last _period day range.
        /// value1 is centered on its midpoint and then doubled so that value1 wil swing between -1 and +1.
        /// value1 is also smoothed with an exponential moving average whose alpha is 0.33.
        ///
        /// Since the smoothing may allow value1 to exceed the _period day price range, limits are introduced to
        /// preclude the transform from blowing up by having an input larger than unity.
        /// </summary>
        /// <param name="window">The IReadOnlyWindow of Indicator Data Points for the history of this indicator</param>
        /// <param name="input">IndicatorDataPoint - the time and value of the next price</param>
        /// <returns></returns>
        protected override decimal ComputeNextValue(IReadOnlyWindow <IndicatorDataPoint> window, IndicatorDataPoint input)
        {
            _maxHigh.Update(input);
            _minLow.Update(input);
            decimal fishx = 0;

            if (IsReady)
            {
                // get some local variables
                var price = input.Value;
                var minL  = _minLow.Current.Value;
                var maxH  = _maxHigh.Current.Value;


                if (price == 0)
                {
                    Current = new IndicatorDataPoint(input.EndTime, 0);
                }
                else
                {
                    // get the value1 from the last time this function was called
                    var v1 = value1[0].Value;

                    try
                    {
                        // compute the EMA of the price and the last value1
                        value1.Add(new IndicatorDataPoint(input.Time,
                                                          .33m * 2m * ((price - minL) / (maxH - minL) - .5m) + .67m * v1));
                    }
                    catch (Exception ex)
                    {
                        throw new Exception(ex.Message + ex.StackTrace);
                    }
                    try
                    {
                        // limit the new value1 so that it falls within positive or negative unity
                        if (value1[0].Value > .9999m)
                        {
                            value1[0].Value = .9999m;
                        }
                        if (value1[0].Value < -.9999m)
                        {
                            value1[0].Value = -.9999m;
                        }
                        var current = Current;

                        // calcuate the Fisher transform according the the formula above and from Ehlers
                        //  Math.Log takes and produces doubles, so the result is converted back to Decimal
                        // The calculation uses the Current.Value from the last time the function was called,
                        //  so an intermediate variable is introduced so that it can be used in the
                        //  calculation before the result is assigned to the Current.Value after the calculation is made.
                        fishx =
                            Convert.ToDecimal(.5 * Math.Log((1.0 + (double)value1[0].Value) / (1.0 - (double)value1[0].Value)));
                    }
                    catch (Exception ex)
                    {
                        throw new Exception(ex.Message + ex.StackTrace);
                    }
                }
            }
            return(fishx);
        }
Exemple #28
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 /// <summary>
 /// Invokes NewPivotPointFormed event
 /// </summary>
 protected virtual void OnNewPivotPointFormed(PivotPoint pivotPoint)
 {
     _windowPivotPoints.Add(pivotPoint);
     NewPivotPointFormed?.Invoke(this, new PivotPointsEventArgs(pivotPoint));
 }
Exemple #29
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        /// <summary>
        /// Computes the next value of this indicator from the given state
        /// </summary>
        /// <param name="input">The input given to the indicator</param>
        /// <returns>A new value for this indicator</returns>
        protected override decimal ComputeNextValue(IBaseDataBar input)
        {
            _windowHighs.Add(input);
            _windowLows.Add(input);

            PivotPoint high = null, low = null;

            if (_windowHighs.IsReady)
            {
                var isHigh      = true;
                var middlePoint = _windowHighs[_lengthHigh];
                for (var k = 0; k < _windowHighs.Size && isHigh; k++)
                {
                    // Skip the middle point
                    if (k == _lengthHigh)
                    {
                        continue;
                    }

                    // Check if current high is below middle point high
                    isHigh = _windowHighs[k].High < middlePoint.High;
                }

                if (isHigh)
                {
                    high = new PivotPoint(PivotPointType.High, middlePoint.High, middlePoint.EndTime);
                }
            }

            if (_windowLows.IsReady)
            {
                var isLow       = true;
                var middlePoint = _windowLows[_lengthLow];
                for (var k = 0; k < _windowLows.Size && isLow; k++)
                {
                    if (k == _lengthLow)
                    {
                        continue;
                    }

                    isLow = _windowLows[k].Low > middlePoint.Low;
                }

                if (isLow)
                {
                    low = new PivotPoint(PivotPointType.Low, middlePoint.Low, middlePoint.EndTime);
                }
            }

            if (high != null)
            {
                OnNewPivotPointFormed(high);
                if (low != null)
                {
                    // Can be the bar forms both high and low pivot points at the same time
                    OnNewPivotPointFormed(low);
                    return((decimal)PivotPointType.Both);
                }
                return((decimal)PivotPointType.High);
            }

            if (low != null)
            {
                OnNewPivotPointFormed(low);
                return((decimal)PivotPointType.Low);
            }

            return((decimal)PivotPointType.None);
        }
 /// <summary>
 ///     Computes the next value of this indicator from the given state
 /// </summary>
 /// <param name="input">The input given to the indicator</param>
 /// <returns>A new value for this indicator</returns>
 protected override decimal ComputeNextValue(T input)
 {
     _window.Add(input);
     return(ComputeNextValue(_window, input));
 }