public void CloneTest() { var exp = new Arsinh(new Number(1)); var clone = exp.Clone(); Assert.Equal(exp, clone); }
public void DerivativeTest() { IExpression exp = new Arsinh(new Mul(new Number(2), new Variable("x"))); IExpression deriv = exp.Differentiate(); Assert.AreEqual("(2 * 1) / sqrt(((2 * x) ^ 2) + 1)", deriv.ToString()); }
public void ExecuteComplexNumberTest() { var complex = new Complex(3, 2); var exp = new Arsinh(new ComplexNumber(complex)); var result = (Complex)exp.Execute(); Assert.Equal(ComplexExtensions.Asinh(complex), result); Assert.Equal(1.983387029916535432347076, result.Real, 15); Assert.Equal(0.5706527843210994007, result.Imaginary, 15); }
public void CalculateTest() { var exp = new Arsinh(new Number(1)); Assert.AreEqual(MathExtentions.Asinh(1), exp.Calculate()); }
public void ArsinhSinh() { var exp = new Arsinh(new Sinh(new Variable("x"))); var expected = new Variable("x"); SimpleTest(exp, expected); }
public void ArsinehDerivativeZeroTest() { var exp = new Arsinh(new Mul(new Number(2), new Variable("z"))); var deriv = Differentiate(exp); Assert.Equal("0", deriv.ToString()); }
public void ArsinehDerivativeTest() { var exp = new Arsinh(new Mul(new Number(2), new Variable("x"))); var deriv = Differentiate(exp); Assert.Equal("(2 * 1) / sqrt(((2 * x) ^ 2) + 1)", deriv.ToString()); }
/// <summary> /// Differentiates the specified expression. /// </summary> /// <param name="expression">The expression.</param> /// <param name="variable">The variable.</param> /// <returns>Returns the derivative.</returns> protected virtual IExpression Arsinh(Arsinh expression, Variable variable) { var sqr = new Pow(expression.Argument.Clone(), new Number(2)); var add = new Add(sqr, new Number(1)); var sqrt = new Sqrt(add); var div = new Div(_Differentiate(expression.Argument.Clone(), variable), sqrt); return div; }
public void ExecuteTest() { var exp = new Arsinh(new Number(1)); Assert.Equal(MathExtensions.Asinh(1), exp.Execute()); }
/// <summary> /// Creates an expression object from <see cref="FunctionToken"/>. /// </summary> /// <param name="token">The function token.</param> /// <returns>An expression.</returns> protected virtual IExpression CreateFunction(FunctionToken token) { IExpression exp; switch (token.Function) { case Functions.Add: exp = new Add(); break; case Functions.Sub: exp = new Sub(); break; case Functions.Mul: exp = new Mul(); break; case Functions.Div: exp = new Div(); break; case Functions.Pow: exp = new Pow(); break; case Functions.Absolute: exp = new Abs(); break; case Functions.Sine: exp = new Sin(); break; case Functions.Cosine: exp = new Cos(); break; case Functions.Tangent: exp = new Tan(); break; case Functions.Cotangent: exp = new Cot(); break; case Functions.Secant: exp = new Sec(); break; case Functions.Cosecant: exp = new Csc(); break; case Functions.Arcsine: exp = new Arcsin(); break; case Functions.Arccosine: exp = new Arccos(); break; case Functions.Arctangent: exp = new Arctan(); break; case Functions.Arccotangent: exp = new Arccot(); break; case Functions.Arcsecant: exp = new Arcsec(); break; case Functions.Arccosecant: exp = new Arccsc(); break; case Functions.Sqrt: exp = new Sqrt(); break; case Functions.Root: exp = new Root(); break; case Functions.Ln: exp = new Ln(); break; case Functions.Lg: exp = new Lg(); break; case Functions.Lb: exp = new Lb(); break; case Functions.Log: exp = new Log(); break; case Functions.Sineh: exp = new Sinh(); break; case Functions.Cosineh: exp = new Cosh(); break; case Functions.Tangenth: exp = new Tanh(); break; case Functions.Cotangenth: exp = new Coth(); break; case Functions.Secanth: exp = new Sech(); break; case Functions.Cosecanth: exp = new Csch(); break; case Functions.Arsineh: exp = new Arsinh(); break; case Functions.Arcosineh: exp = new Arcosh(); break; case Functions.Artangenth: exp = new Artanh(); break; case Functions.Arcotangenth: exp = new Arcoth(); break; case Functions.Arsecanth: exp = new Arsech(); break; case Functions.Arcosecanth: exp = new Arcsch(); break; case Functions.Exp: exp = new Exp(); break; case Functions.GCD: exp = new GCD(); break; case Functions.LCM: exp = new LCM(); break; case Functions.Factorial: exp = new Fact(); break; case Functions.Sum: exp = new Sum(); break; case Functions.Product: exp = new Product(); break; case Functions.Round: exp = new Round(); break; case Functions.Floor: exp = new Floor(); break; case Functions.Ceil: exp = new Ceil(); break; case Functions.Derivative: exp = new Derivative(); break; case Functions.Simplify: exp = new Simplify(); break; case Functions.Del: exp = new Del(); break; case Functions.Define: exp = new Define(); break; case Functions.Vector: exp = new Vector(); break; case Functions.Matrix: exp = new Matrix(); break; case Functions.Transpose: exp = new Transpose(); break; case Functions.Determinant: exp = new Determinant(); break; case Functions.Inverse: exp = new Inverse(); break; case Functions.If: exp = new If(); break; case Functions.For: exp = new For(); break; case Functions.While: exp = new While(); break; case Functions.Undefine: exp = new Undefine(); break; case Functions.Im: exp = new Im(); break; case Functions.Re: exp = new Re(); break; case Functions.Phase: exp = new Phase(); break; case Functions.Conjugate: exp = new Conjugate(); break; case Functions.Reciprocal: exp = new Reciprocal(); break; case Functions.Min: exp = new Min(); break; case Functions.Max: exp = new Max(); break; case Functions.Avg: exp = new Avg(); break; case Functions.Count: exp = new Count(); break; case Functions.Var: exp = new Var(); break; case Functions.Varp: exp = new Varp(); break; case Functions.Stdev: exp = new Stdev(); break; case Functions.Stdevp: exp = new Stdevp(); break; default: exp = null; break; } var diff = exp as DifferentParametersExpression; if (diff != null) diff.ParametersCount = token.CountOfParams; return exp; }