Exemplo n.º 1
0
 private void write_square_wave_period(
     Channel channel,
     SquareWave square)
 {
     square.period =
         (uint)(((SOUND_MAX_FREQUENCY + 1) - channel.frequency) * 4);
 }
Exemplo n.º 2
0
        private void DrawSquareWave()
        {
            // Set the x axis range to be the period of the wave.
            m_GraphXAxisRange = double.Parse(textBox_Period.Text);

            // Get the amplitude of the wave from the user
            double amplitude = Convert.ToDouble(textBox_Amplitude.Text);

            // Get the phase of the wave from the user
            double phase = Convert.ToDouble(textBox_Phase.Text);

            // Create the square wave
            //m_SquareWave = new SquareWave(amplitude,
            //                              m_GraphXAxisRange,
            //                              phase,
            //                              m_SamplingPeriod);

            m_SquareWave = new SquareWave(amplitude,
                                          m_GraphXAxisRange,
                                          (int)phase,
                                          m_SamplingPeriod);

            // Set the graph y axis limits
            m_GraphAxisYMax = Math.Round(amplitude + (amplitude / 4), 2);
            m_GraphAxisYMin = -1 * m_GraphAxisYMax;


            // Set the current wave
            m_currentWave = m_SquareWave;
        }
        public void HaveHeightAndWidth()
        {
            var squareWave = new SquareWave(10, 10, 10, 0);

            Assert.IsTrue(squareWave.Height > 0);
            Assert.IsTrue(squareWave.Width > 0);
        }
Exemplo n.º 4
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 public void Constructor_ReturnsSquareWave()
 {
     double[] dutyCycles = { 0.0, 0.5, 1.0 };
     foreach (var dutyCycle in dutyCycles)
     {
         SquareWave sw = new SquareWave(dutyCycle);
         Assert.IsInstanceOfType(sw, typeof(SquareWave));
     }
 }
Exemplo n.º 5
0
    void Awake()
    {
        sawAudioWave    = new SawWave();
        squareAudioWave = new SquareWave();
        sinusAudioWave  = new SinusWave();

        amplitudeModulationOscillator = new SinusWave();
        frequencyModulationOscillator = new SinusWave();

        sampleRate = AudioSettings.outputSampleRate;
    }
Exemplo n.º 6
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        //Below runs the necessary scan on the APM
        public async Task <Method> RunScan()
        {
            List <ScanDatabase> allDb = await App.Database.GetScanDatabasesAsync();

            ScanDatabase _database = await App.Database.GetScanAsync(allDb.Count);

            ScanParams instance = new ScanParams();

            switch (_database.VoltamType)
            {
            case "Linear Voltammetry":
                LinearSweep linSweep = instance.LinSweep(_database);

                linSweep.Ranging.StartCurrentRange   = new CurrentRange(5);
                linSweep.Ranging.MaximumCurrentRange = new CurrentRange(6);
                linSweep.Ranging.MaximumCurrentRange = new CurrentRange(3);

                return(linSweep);

            case "Cyclic Voltammetry":
                CyclicVoltammetry cVoltammetry = instance.CV(_database);

                cVoltammetry.Ranging.StartCurrentRange   = new CurrentRange(5);
                cVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(6);
                cVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(3);

                return(cVoltammetry);

            case "Square Wave Voltammetry":
                SquareWave squareWave = instance.SWV(_database);

                squareWave.Ranging.StartCurrentRange   = new CurrentRange(5);
                squareWave.Ranging.MaximumCurrentRange = new CurrentRange(6);
                squareWave.Ranging.MaximumCurrentRange = new CurrentRange(3);

                return(squareWave);

            case "Alternating Current Voltammetry":
                ACVoltammetry acVoltammetry = instance.ACV(_database);

                acVoltammetry.Ranging.StartCurrentRange   = new CurrentRange(5);
                acVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(6);
                acVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(3);

                return(acVoltammetry);

            default:
                //Add code to notify user that something has gone wrong and needs to be fixed

                return(null);
            }
        }
Exemplo n.º 7
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 public void Value_ReturnsDouble()
 {
     double[] dutyCycles = { 0.0, 0.5, 1.0 };
     double[] phases     = { 0.0, 0.25 * Math.PI, 0.5 * Math.PI, Constants._2PI };
     foreach (double dutyCycle in dutyCycles)
     {
         SquareWave sw = new SquareWave(dutyCycle);
         foreach (double phase in phases)
         {
             Assert.IsInstanceOfType(sw.Value(phase), typeof(double));
         }
     }
 }
Exemplo n.º 8
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        public void Value_Returns1AlwaysForDutyCycleOf1()
        {
            double dutyCycle = 1.0;

            double[]   phases   = { 0.0, 0.25 * Math.PI, 0.5 * Math.PI, Constants._2PI };
            double     expected = 1.0;
            SquareWave sw       = new SquareWave(dutyCycle);

            foreach (double phase in phases)
            {
                Assert.AreEqual(sw.Value(phase), expected);
            }
        }
Exemplo n.º 9
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        public SquareWave SWV(ScanDatabase _database)   //Set the parameters for a square wave scan
        {
            SquareWave squareWave = new SquareWave
            {
                BeginPotential = (float)_database.StartingPotential,
                EndPotential   = (float)_database.EndingPotential,
                StepPotential  = (float)_database.PotentialStep,
                PulseAmplitude = (float)_database.Amplitude,
                Frequency      = (float)_database.Frequency
            };

            return(squareWave);
        }
Exemplo n.º 10
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        public void Constructor_ThrowsArgumentOutOfRangeException_ForDutyCycleGreatherThan1()
        {
            double dutyCycle = 1.000001;

            try
            {
                SquareWave sw = new SquareWave(dutyCycle);
            }
            catch (ArgumentOutOfRangeException e)
            {
                Assert.IsInstanceOfType(e, typeof(ArgumentOutOfRangeException));
                StringAssert.Contains(e.Message, Constants.DutyCycleAbove1);
                return;
            }
            Assert.Fail();
        }
Exemplo n.º 11
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        public void TestSquareWave()
        {
            Calibration.Initialize();

            IBGCStream stream =
                new SquareWave(1f, 400f)
                .Window(DURATION)
                .Normalize(LEVEL);

            bool success = WaveEncoding.SaveStream(
                filepath: DataManagement.PathForDataFile("Test", "squareWave.wav"),
                stream: stream,
                overwrite: true);

            Assert.IsTrue(success);
        }
Exemplo n.º 12
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        public void Constructor_ThrowsArgumentOutOfRangeException_ForNegativeDutyCycle()
        {
            double dutyCycle = -1.0;

            try
            {
                SquareWave sw = new SquareWave(dutyCycle);
            }
            catch (ArgumentOutOfRangeException e)
            {
                Assert.IsInstanceOfType(e, typeof(ArgumentOutOfRangeException));
                StringAssert.Contains(e.Message, Constants.DutyCycleNegativeMessage);
                return;
            }
            Assert.Fail();
        }
Exemplo n.º 13
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        public void Value_ReturnsKnownResults_ForKnownPhases_BeforeAndAfterSetDutyCycle()
        {
            double initialDutyCycle = 0.25;

            double[]   initialPhases         = { 0.0, 0.2, initialDutyCycle *Constants._2PI, 3.0, Constants._2PI };
            double[]   initialexpectedValues = { 1.0, 1.0, 0.0, 0.0, 1.0 };
            SquareWave sw = new SquareWave(initialDutyCycle);

            TestMethods.TestKnownInputsAgainstKnownResults(sw, initialPhases, initialexpectedValues);

            double finalDutyCycle = 0.6;

            double[] finalPhases         = { 0.0, 0.2, initialDutyCycle *Constants._2PI, 3.0, 6.0, Constants._2PI };
            double[] finalExpectedValues = { 1.0, 1.0, 1.0, 1.0, 0.0, 1.0 };
            sw.DutyCycle = finalDutyCycle;
            TestMethods.TestKnownInputsAgainstKnownResults(sw, finalPhases, finalExpectedValues);
        }
    void Awake()
    {
        sawAudioWave    = new SawWave();
        squareAudioWave = new SquareWave();
        sinusAudioWave  = new SinusWave();

        amplitudeModulationOscillator = new SinusWave();
        frequencyModulationOscillator = new SinusWave();

        // Gets the Sample Rate of the audio system in Unity
        sampleRate = AudioSettings.outputSampleRate;
        //Debug.Log(sampleRate);

        //  The value that is assigned to the variable volume, this is the actual volume of the synth
        volumeValue = 0.3f;                             //  Change this value to make it louder
        volume      = volumeValue;
    }
Exemplo n.º 15
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        public void Value_ReturnsKnownValues_ForKnownPhases()
        {
            double dutyCycle = 0.25;

            double[]   phases         = { 0.0, 0.2, dutyCycle *Constants._2PI, 3.0, Constants._2PI };
            double[]   expectedValues = { 1.0, 1.0, 0.0, 0.0, 1.0 };
            SquareWave sw             = new SquareWave(dutyCycle);

            Assert.AreEqual(phases.Length, expectedValues.Length, "Known inputs and results test sets do not contain the same number of values.");
            for (int count = 0; count < phases.Length; count++)
            {
                double phase    = phases[count];
                double actual   = sw.Value(phase);
                double expected = expectedValues[count];
                string message  = string.Format("Phase: {0}\nExpected: {1}\nActual:{2}", phase, expected, actual);
                Assert.AreEqual(actual, expected, message);
            }
        }
Exemplo n.º 16
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        public void SetDutyCycle_ThrowsArgumentOutOfRangeException_ForNegativeDutyCycle()
        {
            double     initialDutyCycle = 0.5;
            SquareWave sw = new SquareWave(initialDutyCycle);

            try
            {
                double negativeDutyCycle = -0.25;
                sw.DutyCycle = negativeDutyCycle;
            }
            catch (ArgumentOutOfRangeException e)
            {
                Assert.IsInstanceOfType(e, typeof(ArgumentOutOfRangeException));
                StringAssert.Contains(e.Message, Constants.DutyCycleNegativeMessage);
                return;
            }
            Assert.Fail();
        }
Exemplo n.º 17
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        public void SquareWave_1000_samples_500000_iterations_4_channels()
        {
            var buffers = new[]
            {
                new float[1000],
                new float[1000],
                new float[1000],
                new float[1000]
            };

            var target = new SquareWave();

            target.Format = new WaveFormat(44100, 4);

            for (int i = 0; i < 500000; i++)
            {
                target.Process(buffers, 1000);
            }
        }
Exemplo n.º 18
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        public void Set(
            string Trig,
            Signal Signal           = null,
            VirtualPath VirtualPath = null,
            SquareWave SquareWave   = null,
            SetVar SetVar           = null,
            string PortOut          = null,
            string Next             = null
            )
        {
            SetCommand cmd = new SetCommand(
                inSignal: Signal,
                inVirtualPath: VirtualPath,
                inSquareWave: SquareWave,
                inSetVar: SetVar,
                inPortOut: PortOut,
                inNext: Next
                );

            PublicController.Instance.Register(Trig, cmd);
        }
        //Sets the scan parameters
        public async Task <Method> RunScan()
        {
            //Grabs the most recent database to get the required parameters
            List <ScanDatabase> allDb = await App.Database.GetScanDatabasesAsync();

            ScanDatabase _database = await App.Database.GetScanAsync(allDb.Count);

            //Gets an instance of ScanParams
            ScanParams instance = new ScanParams();

            switch (_database.VoltamType)           //Switch which invokes the correct type of scan
            {
            case "Alternating Current Voltammetry": //Sets an alternating current voltammetric scan
                using (ACVoltammetry acVoltammetry = instance.ACV(_database))
                {
                    acVoltammetry.SmoothLevel = 0;
                    acVoltammetry.Ranging.StartCurrentRange   = new CurrentRange(CurrentRanges.cr10uA);     //Sets the range that the potentiostat will use to detect the current
                    acVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100uA);
                    acVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100nA);

                    return(acVoltammetry);
                }

            case "Cyclic Voltammetry":       //Sets a cyclic voltammetric scan
                using (CyclicVoltammetry cVoltammetry = instance.CV(_database))
                {
                    cVoltammetry.SmoothLevel = 0;
                    cVoltammetry.Ranging.StartCurrentRange   = new CurrentRange(CurrentRanges.cr10uA);     //Sets the range that the potentiostat will use to detect the current
                    cVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100uA);
                    cVoltammetry.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100nA);

                    return(cVoltammetry);
                }

            case "Differential Pulse Voltammetry":       //Sets a differential pulse voltammetric scan
                using (DifferentialPulse differentialPulse = instance.DPV(_database))
                {
                    differentialPulse.SmoothLevel = 0;
                    differentialPulse.Ranging.StartCurrentRange   = new CurrentRange(CurrentRanges.cr1uA);     //Sets the range that the potentiostat will use to detect the current
                    differentialPulse.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr1uA);
                    differentialPulse.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr10nA);

                    return(differentialPulse);
                }

            case "Linear Voltammetry":       //Sets a linear voltammetric scan
                using (LinearSweep linSweep = instance.LinSweep(_database))
                {
                    linSweep.SmoothLevel = 0;
                    linSweep.Ranging.StartCurrentRange   = new CurrentRange(CurrentRanges.cr10uA);     //Sets the range that the potentiostat will use to detect the current
                    linSweep.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100uA);
                    linSweep.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100nA);

                    return(linSweep);
                }

            case "Square Wave Voltammetry":       //Sets a square wave voltammetric scan
                using (SquareWave squareWave = instance.SWV(_database))
                {
                    squareWave.SmoothLevel = 0;
                    squareWave.Ranging.StartCurrentRange   = new CurrentRange(CurrentRanges.cr10uA);     //Sets the range that the potentiostat will use to detect the current
                    squareWave.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100uA);
                    squareWave.Ranging.MaximumCurrentRange = new CurrentRange(CurrentRanges.cr100nA);

                    return(squareWave);
                }

            default:
                //Add code to notify user that something has gone wrong and needs to be fixed

                return(null);
            }
        }
        public void BeAWave()
        {
            var squareWave = new SquareWave(10, 10, 10, 0);

            Assert.IsInstanceOf <Wave>(squareWave);
        }
Exemplo n.º 21
0
 public void TestInitialise()
 {
     target        = new SquareWave();
     target.Format = new WaveFormat(44100, 2);
 }
Exemplo n.º 22
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        public void TestBiQuadFilters()
        {
            Calibration.Initialize();

            {
                //Bandpass Filtered Sine Wave, Matched Frequency
                IBGCStream stream =
                    new SquareWave(1f, 400f)
                    .BiQuadBandpassFilter(400f)
                    .Window(DURATION)
                    .Normalize(LEVEL);

                bool success = WaveEncoding.SaveStream(
                    filepath: DataManagement.PathForDataFile("Test", "BiQuadMostThroughBandWave.wav"),
                    stream: stream,
                    overwrite: true);

                Assert.IsTrue(success);
            }

            {
                //Bandpass Filtered Sine Wave, 2x Frequency
                IBGCStream stream =
                    new SquareWave(1f, 400f)
                    .BiQuadBandpassFilter(800f)
                    .Window(DURATION)
                    .Normalize(LEVEL);

                bool success = WaveEncoding.SaveStream(
                    filepath: DataManagement.PathForDataFile("Test", "BiQuadTooHighBandWave.wav"),
                    stream: stream,
                    overwrite: true);

                Assert.IsTrue(success);
            }
            {
                //Bandpass Filtered Sine Wave, Half Frequency
                IBGCStream stream =
                    new SquareWave(1f, 400f)
                    .BiQuadBandpassFilter(200f)
                    .Window(DURATION)
                    .Normalize(LEVEL);

                bool success = WaveEncoding.SaveStream(
                    filepath: DataManagement.PathForDataFile("Test", "BiQuadTooLowBandWave.wav"),
                    stream: stream,
                    overwrite: true);

                Assert.IsTrue(success);
            }

            {
                //Notch Filtered Square Wave, Matched Frequency
                IBGCStream stream =
                    new SquareWave(1f, 400f)
                    .BiQuadNotchFilter(400f)
                    .Window(DURATION)
                    .Normalize(LEVEL);

                bool success = WaveEncoding.SaveStream(
                    filepath: DataManagement.PathForDataFile("Test", "BiQuadNotchFilteredSquareWave.wav"),
                    stream: stream,
                    overwrite: true);

                Assert.IsTrue(success);
            }

            {
                //Notch Filtered Sine Wave, Matched Frequency
                IBGCStream stream =
                    new SineWave(1f, 400f)
                    .BiQuadNotchFilter(400f)
                    .Window(DURATION)
                    .Normalize(LEVEL);

                bool success = WaveEncoding.SaveStream(
                    filepath: DataManagement.PathForDataFile("Test", "BiQuadNotchFilteredSineWave.wav"),
                    stream: stream,
                    overwrite: true);

                Assert.IsTrue(success);
            }

            {
                //Notch Filtered Sine Wave, +10 Hz Mismatch
                IBGCStream stream =
                    new SineWave(1f, 400f)
                    .BiQuadNotchFilter(410f)
                    .Window(DURATION)
                    .Normalize(LEVEL);

                bool success = WaveEncoding.SaveStream(
                    filepath: DataManagement.PathForDataFile("Test", "BiQuadNotchFiltered410SineWave.wav"),
                    stream: stream,
                    overwrite: true);

                Assert.IsTrue(success);
            }
        }
Exemplo n.º 23
0
 public Harmonic(CustomSoundProvider provider)
 {
     Sine = new SineWave(provider);
     Square = new SquareWave(provider);
     Triangle = new TriangleWave(provider);
     Sawtooth = new SawtoothWave(provider);
     Amplitude = 0.25f;
 }