SSPC-Tester/SSPCTester.Tests/CalculationTests.cs

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using SSPCTester.Devices.Interfaces;
using SSPCTester.Logic.Calculation;
using Xunit;
namespace SSPCTester.Tests;
public class CurveMetricsTests
{
/// <summary>构造一段 V(t) = Vmax*(1-exp(-t/tau)) 形状的上升曲线。</summary>
private static CurveData MakeRising(double vMax = 28, double tauSec = 0.0005, int rate = 100_000, double duration = 0.01, double trigger = 0.0025)
{
int n = (int)(rate * duration);
var v = new double[n];
for (int i = 0; i < n; i++)
{
double t = (double)i / rate - trigger;
v[i] = t <= 0 ? 0 : vMax * (1 - System.Math.Exp(-t / tauSec));
}
return new CurveData { SampleRateHz = rate, TriggerTimeSec = trigger, Voltage = v };
}
private static CurveData MakeFalling(double vMax = 28, double tauSec = 0.0005, int rate = 100_000, double duration = 0.01, double trigger = 0.0025)
{
int n = (int)(rate * duration);
var v = new double[n];
for (int i = 0; i < n; i++)
{
double t = (double)i / rate - trigger;
v[i] = t <= 0 ? vMax : vMax * System.Math.Exp(-t / tauSec);
}
return new CurveData { SampleRateHz = rate, TriggerTimeSec = trigger, Voltage = v };
}
[Fact]
public void OnTimeMs_ReachesNinetyPercent_AtAboutMinusLogPointOneTau()
{
var c = MakeRising();
double onMs = CurveMetrics.OnTimeMs(c, 28, 0.9);
// 90% 时刻 t = -tau * ln(0.1) ≈ 1.151 ms
Assert.InRange(onMs, 1.1, 1.2);
}
[Fact]
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public void RiseTimeMs_TonToNinety_AboutNinetyPercentTime()
{
var c = MakeRising();
double rt = CurveMetrics.RiseTimeMs(c, 28);
// ln(0.9/0.1) = ln 9 ≈ 2.197rt = tau * 2.197 ≈ 1.099 ms
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Assert.InRange(rt, 1.1, 1.2);
}
[Fact]
public void AnalyzeRising_ReturnsTonToNinetyIndexesAndDuration()
{
var c = MakeRising();
var mark = CurveMetrics.AnalyzeRising(c, 28);
int triggerIndex = (int)Math.Round(c.TriggerTimeSec * c.SampleRateHz);
int expectedEnd = CurveMetrics.FirstReachIndex(c.Voltage, 28 * 0.9, rising: true, triggerIndex);
int expectedStart = triggerIndex + 1;
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Assert.True(mark.IsValid);
Assert.Equal(expectedStart, mark.StartIndex);
Assert.Equal(expectedEnd, mark.EndIndex);
Assert.Equal(c.Voltage[expectedStart], mark.StartThresholdV, 6);
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Assert.Equal((c.TimeAt(expectedEnd) - c.TimeAt(expectedStart)) * 1000.0, mark.DurationMs, 6);
Assert.Equal(mark.DurationMs, CurveMetrics.RiseTimeMs(c, 28), 6);
}
[Fact]
public void OffTimeMs_FallingToTenPercent()
{
var c = MakeFalling();
double off = CurveMetrics.OffTimeMs(c, 28, 0.1);
Assert.InRange(off, 1.1, 1.2);
}
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[Fact]
public void AnalyzeFalling_ReturnsStableHighToTenIndexesAndDuration()
{
var c = MakeFalling();
var mark = CurveMetrics.AnalyzeFalling(c, 28);
int triggerIndex = (int)Math.Round(c.TriggerTimeSec * c.SampleRateHz);
int expectedEnd = CurveMetrics.FirstReachIndex(c.Voltage, 28 * 0.1, rising: false, triggerIndex);
int expectedStart = triggerIndex + 1;
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Assert.True(mark.IsValid);
Assert.Equal(expectedStart, mark.StartIndex);
Assert.Equal(expectedEnd, mark.EndIndex);
Assert.Equal(c.Voltage[expectedStart], mark.StartThresholdV, 6);
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Assert.Equal((c.TimeAt(expectedEnd) - c.TimeAt(expectedStart)) * 1000.0, mark.DurationMs, 6);
Assert.Equal(mark.DurationMs, CurveMetrics.FallTimeMs(c, 28), 6);
}
[Fact]
public void AnalyzeRising_StartsAtSustainedRiseAndEndsAtFirstRawNinetyPercent()
{
const int rate = 1_000_000;
const double trigger = 0.0002;
int triggerIndex = (int)Math.Round(trigger * rate);
var v = Enumerable.Repeat(0.0, 2_000).ToArray();
v[triggerIndex + 100] = -4.0;
v[triggerIndex + 101] = 2.0;
v[triggerIndex + 102] = 0.0;
int riseStart = triggerIndex + 500;
for (int i = riseStart; i < v.Length; i++)
{
double progress = Math.Clamp((i - riseStart) / 60.0, 0.0, 1.0);
v[i] = 5.0 * progress;
}
var curve = new CurveData { SampleRateHz = rate, TriggerTimeSec = trigger, Voltage = v };
var mark = CurveMetrics.AnalyzeRising(curve, 5.0);
int expectedEnd = CurveMetrics.FirstReachIndex(v, 4.5, rising: true, riseStart);
Assert.True(mark.IsValid);
Assert.InRange(mark.StartIndex, riseStart - 3, riseStart + 5);
Assert.Equal(expectedEnd, mark.EndIndex);
}
[Fact]
public void AnalyzeFalling_StartsAtSlowDropAndEndsAtFirstRawTenPercent()
{
const int rate = 1_000_000;
const double trigger = 0.0002;
int triggerIndex = (int)Math.Round(trigger * rate);
var v = Enumerable.Repeat(3.0, 2_000).ToArray();
int fallStart = triggerIndex + 300;
for (int i = fallStart; i < triggerIndex + 850; i++)
v[i] = 3.0 - 0.55 * (i - fallStart) / 550.0;
v[triggerIndex + 850] = 5.0;
for (int i = triggerIndex + 851; i < v.Length; i++)
{
double progress = Math.Clamp((i - (triggerIndex + 851)) / 45.0, 0.0, 1.0);
v[i] = Math.Max(-0.2, 2.45 * (1.0 - progress));
}
var curve = new CurveData { SampleRateHz = rate, TriggerTimeSec = trigger, Voltage = v };
var mark = CurveMetrics.AnalyzeFalling(curve, 3.0);
int expectedEnd = CurveMetrics.FirstReachIndex(v, 0.3, rising: false, fallStart);
Assert.True(mark.IsValid);
Assert.InRange(mark.StartIndex, fallStart - 5, fallStart + 30);
Assert.Equal(expectedEnd, mark.EndIndex);
}
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[Fact]
public void AnalyzeTransition_ReturnsInvalidWhenThresholdsAreNotReached()
{
var risingCurve = new CurveData
{
SampleRateHz = 100_000,
TriggerTimeSec = 0,
Voltage = Enumerable.Repeat(0.0, 100).ToArray()
};
var fallingCurve = new CurveData
{
SampleRateHz = 100_000,
TriggerTimeSec = 0,
Voltage = Enumerable.Repeat(28.0, 100).ToArray()
};
var rising = CurveMetrics.AnalyzeRising(risingCurve, 28);
var falling = CurveMetrics.AnalyzeFalling(fallingCurve, 28);
Assert.False(rising.IsValid);
Assert.False(falling.IsValid);
Assert.Equal(-1, rising.StartIndex);
Assert.Equal(-1, falling.EndIndex);
Assert.True(double.IsNaN(CurveMetrics.RiseTimeMs(risingCurve, 28)));
Assert.True(double.IsNaN(CurveMetrics.FallTimeMs(fallingCurve, 28)));
}
[Fact]
public void EstimateVMax_NearActualMax()
{
var c = MakeRising();
double v = CurveMetrics.EstimateVMax(c.Voltage);
Assert.InRange(v, 27, 28.001);
}
}
public class PowerLossTests
{
[Fact]
public void VoltageDrop_Subtracts()
=> Assert.Equal(1.5, PowerLoss.VoltageDrop(28, 26.5), 3);
[Fact]
public void Loss_PinMinusPout()
=> Assert.Equal(28 * 1.0 - 26.5 * 1.0, PowerLoss.LossWatts(28, 1, 26.5, 1), 3);
[Fact]
public void Efficiency_Percentage()
{
double e = PowerLoss.EfficiencyPct(28, 1, 26.5, 1);
Assert.InRange(e, 94, 95);
}
[Fact]
public void Efficiency_ZeroInputReturnsZero()
=> Assert.Equal(0.0, PowerLoss.EfficiencyPct(0, 0, 0, 0));
}