PTC Mathcad Prime 3.0 Worksheet Library Building Thermal Analysis 45 Worksheets The Building Thermal Analysis worksheet collection covers topics like conduction, convection, solar radiation, thermal radiation, and heat flow for infrastructure including walls, windows, rooms, pipes, inclined surfaces, boilers, and chimneys. More advanced worksheets solve transient models for single walls and entire Heating Ventilation and Air Conditioning (HVAC) systems. Building Structural Design 33 Worksheets This worksheet collection contains a wide range of structural design problems. These worksheets demonstrate how PTC Mathcad Prime 3.0 can solve basic structural design problems within a well-documented report. The worksheets follow regulating building and design codes like the American Concrete Institute (ACI) and the American Society of Civil Engineers (ASCE) Standards. Shear and moment curves for beam loading; design of columns, flat plates, base plates, retaining walls, and footings; and wind and seismic loading are some of the worksheet topics. Chemical Engineering 22 Worksheets This set of PTC Mathcad Prime 3.0 worksheets cover topics including fluid flow, phase changes, heat exchangers, vaporizers, and pressure drops for cases involving both liquids and gases. More advanced worksheets include model PID controllers heating a tank of liquid, solve fluid dynamic problems in both parallel and series, and use the McCabe-Thiele Method for binary distillation. Custom Functions 6 Worksheets These custom functions enable the user to take a PTC Mathcad Prime 3.0 worksheet and write STL, DXF, HDF5, and C++. Users can turn mathematic models in their PTC Mathcad Prime 3.0 worksheet into 3D renderings using WriteSTL and WriteDXF. User also can export PTC Mathcad Prime 3.0 matrices as C++ code to assist in the verification of FORTRAN or C++ codes. Users gain the ability to develop and distribute custom functions. This means legacy code (C, C++, and FORTRAN) can be wrapped as additional Mathcad Prime 3.0 functions. Differential Equations 62 Worksheets The Differential Equations worksheets will provide the user with an overview of ordinary differential equations (ODEs). The worksheet collection is designed to show the user where ODEs come from and how to solve them in PTC Mathcad Prime 3.0. Topics covered include: boundary conditions, first and second order differential equations, homogeneous and nonhomogeneous differential equations, Euler’s Method, Eigenvalues, linear and nonlinear differential equations, Bessel functions, and Legendre polynomials. Electrical Power Systems Engineering 35 Worksheets This worksheet collection carries out common design calculations for electrical power systems. Power transmission and distribution, power system protection, and power system electrical transients are the three major topics discussed. PTC Mathcad Prime 3.0 capabilities including complex arithmetic, matrices, equation solving, and plotting are showcased while tackling these problems. Finite Element Beginnings 152 Worksheets The Finite Element Beginnings collection is comprised of six chapters that cover the finite element method. This method is a numerical analysis technique used to obtain solutions to the differential equations that describe a wide variety of physical and nonphysical problems. The six chapters cover: finite element beginnings, the discrete approach, finite elements of elastic continua, element interpolation and shape functions, mapped elements, and the method of weighted residuals. Mathcad Prime Tutorials with Physics Examples 22 Worksheets This set of PTC Mathcad Prime 3.0 worksheets walk users through elementary physics problems while teaching them the basics of PTC Mathcad Prime 3.0. Upon completion of the tutorials, the user will be able to: write equations that contain constants, variables, and units; solve and graph equations; statistically analyze a set of data; and linearly fit a set of data. Miscellaneous Worksheets 65 Worksheets This worksheet collection is a good resource for a user of any discipline as it contains material for wide range of applications. These applications include Mechanical, Electrical, Civil, and Environmental Engineering in addition to topics including data regression, complex numbers, solving systems of equations, financial risk management, and response surface modeling. Programming in PTC Mathcad 3.0 29 Worksheets This set of programming worksheets show the user the opportunities for programming with PTC Mathcad Prime 3.0. Many of PTC Mathcad Prime 3.0’s computational and connectivity features are discussed throughout the set. Programming worksheets cover for and while loops; if, else, and else if statements; and continue, break, and return operators. Topics in Electrical Engineering 26 Worksheets These worksheets perform common design calculations from several branches of electrical engineering. These branches include circuits, feedback analysis, signal processing, transfer functions, and electromagnetics. These worksheets illustrate how PTC Mathcad Prime 3.0 is a useful tool for solving a user’s electrical engineering problems. Building Thermal Analysis 1.1_Heat_Conduction_in_Multila yered_Walls 1.2_Heat_Conduction_Through_ Insulated_Pipes 1.3_Walls_with_Internal_Heat_G eneration 1.4_Conduction_Shape_Factors _-_Pipe_Buried_in_Soil 1.5_Effect_of_Solar_Radiation_ on_Exterior_Walls 1.6_Thermal_Analysis_of_Unhe ated_Spaces 10.1 Laplace Transfer Functions for Building Thermal Control 10.2 Transient Building Response Using Numerical Inversion of Laplace Domain Response 10.3_Thermal_Control_and_Tra nsient_Response_of_a_Heating _System 10.4_ZTransforms_and_Their_Applicati on_to_Digital_Thermal_Control_ and_Simulation 11.1 Boiler, Piping System, and Pump 11.2 Expansion Tank 11.3 Chimney System Design 2.1_Lumped_Parameter_Model_ and_the_Thermal_Network_Met hod 2.2_Transient_Conduction_in_S emi-Infinite_Slab 2.3_Semi-Infinite_Slab__Radiant_Heat_Flux_on_Floor 2.4_Semi-Infinite_Slab__Convective_Boundary_Conditio n 2.5_Simple_Transient_Model_fo r_a_Wall 3.1_Steady-State_TwoDimensional_Analysis_of_Therm al_Bridges 3.2_Heat_Flow_in_Basements 3.3_Transient_OneDimensional_Finite_Difference_ Wall_Model 4.1_Principles_of_Steady_Perio dic_Analysis_of_Wall_Heat_Flo w 4.2_Thermal_Admittance_of_a_ Multilayered_Wall 4.3_SteadyPeriodic_Heat_Transfer_in_Multi layered_Walls 5.1_Natural_Convection_in_Wall _Cavities_and_Windows 5.2_Convective_Heat_Transfer_ Coefficients_in_Rooms 5.3_Wind_Heat_Transfer_Coeffi ecient 5.4_Infiltration 6.1_Calculation_of_View_Factor s_in_a_Rectangular_Room_with _One_Window 6.2_Calculation_of_Thermal_Ra diation_Properties 6.3.1_Combined_Raduation_Co nvection_Heat_Transfer_in_Cavi ties_and_Thermal_Resistance_o f_Windows 6.3.2_Measurements_of_Air_Te mperature 6.3.3_Combined_RadiationConvection_Heat_Loss_from_Pi pe 6.3_Combined_Radiation_and_ Convection 7.1_Solar_Radiation_on_Incline d_Surfaces 7.1_Solar_Radiation_on_Incline d_Surfaces_PROBLEMS!!! 7.2_Solar_Properties_of_Windo ws 7.3_Solar_Radiation_Transmitte d_by_Windows 7.4 Solar Shading Calculations and Design of Overhangs 8.1_Psychrometry_and_Thermo dynamic_Properties_of_Moist_Ai r 8.2_Properties_of_Moist_Air__Three_Cases 8.3_Thermal_Comfort_Calculati on 9.1_First_Order_Room_Model 9.2_Detailed_SteadyPeriodic_Zone_Model_and_Heat ing_Load_Calculations 9.3_SteadyPeriodic_Zone_Model_and_Cool ing_Load_Calculations Building Structural Design 1.1_Simple_Span_Beams 1.2_Beams_with_Uniform_Load _and_End_Moments 1.3_Single_Span_Beams__Shear_and_Moment 10.1_Material_Propreties,_Devel opment,_and_Splice_Lengths 2.1 Composite Beam Section Properties 2.2 Shear Capacity of Welded Studs 2.3 Section Properties of BuiltUp Steel Sections 3.1 Continous One Way Slabs 3.2 Reinforced Concrete Beams - Size Selection 3.3 Continous Beams - Flexural Reinforcement 3.4_Shear_Reinforcement 3.5_Reinforced_Concrete_Secti on_Properties 4.1_Rectangular_Tied_Columns 4.2_Effective_Lengths_and_Criti cal_Loads 4.3_Moment_Magnification 5.1_Wide_flange_columns 5.2_Tubular_Steel_Columns 5.3_Steel_Pipe_Columns 5.4_Steel_Column_Base_Plates 5.5_Elastic_Effective_Length_Fa ctors 5.6_Inelastic_Effective_Length_ Factors 6.1_Direct_Design_Moments_A nd_Flexural_Reinforcement 6.2_Design_of_Flat_Plates_for_ Shear 7.1_Spread_Footings 7.2_Pile_Footings 7.3_Pile_Cap_Configurations 7.4_As_Driven_Pile_Group_Ana lysis 8.1_Reinforced_Concrete_Retai ning_Walls_with_Level_or_Surc harged_Backfill 8.2_Reinforced_Concrete_Retai ning_Walls_with_Sloping_Backh ill Chemical Engineering 2D Linear Interpolation Automatic Optimisation Controller Gains Energy Transfer Across a Heat Exchanger Equilibrium Stages Required to Separate Propane-Pentane FitData_ Antoine Equation Flowrate Between Two Reservoirs Assisted By A Pump Flow Through a Pipe Flow Through a Pump Heat Transfer Coefficient For Pool Boiling McCabe-Thiele Distillation Pressure Drop in a Venturi Pressure Drop of a Power-Law Fluid Pumps in Parallel Single Component Vaporiser Single Component Vaporiser under PI Control Specific Enthalpy of Ethanol Tank Heating under PI Control Tank Heating under PID Control Transient Draining of Tanks Transient Heat Exchange Through Three Tanks In Series Two-Phase Pressure Drop Vapour-Liquid Equilibria Custom Functions Mathcad_HDF mat2cplusplus 4 shape samples plus tree WRITE DXF 4 shape samples plus tree Generate STL3 Differential Equations 0 Introduction to Ordinary Differential Equations 0.1 Solutions to Differential Equations and Integral Curves 0.2 Classifying Differential Equations 0.3 Initial Boundary Value Problems 0.4 Some Applications That Lead to Differential Equations 1 First Order Ordinary Differential Equations and Application 1.1 Separable Differential Equations 1.1.1 Application Population Dynamics 1.1.2 Application Newton's Law of Cooling 1.1.3 Miscellaneous Applications from Mechanics 1.2 Exact Differential Equations 1.3 Integrating Factors 1.4 Algebraically Homogeneous Differential Equations 1.4A Detail for Section 1.4 1.5 Linear Differential Equations 1.5A Detail for Section 1.5 1.6 Numerical Methods for First Order Ordinary Differential Equations 1.6.1 Euler's Method 1.6.2 The Modified Euler Method 1.6.3 The Fourth Order RungeKutta Method 1.6.4 Fourth Order AdamsBashforth Method A Multistep Method 1.6.4A Detail for Section 1.6.4 1.6.5 The Adams-Moulton and Adams-Bashforth-Moulton Predictor-Corrector Methods 1.7 Miscellaneous First Order Differential Equations and Applications 2 Second Order Linear Differential Equations - Methods and Applications 2.1 General Theory of Second Linear Differential Equations 2.2 Homogeneous Linear Differential Equations with Constant Coefficients 2.3 Nonhomogeneous Linear Differential Equations 2.3.1 The Method of Undetermined Coefficients 2.3.2 The Method of Variation of Parameters 2.4 Applications from Mechanical Vibrations and Electric Circuits 2.4.1 Free Vibrations of a Mechanical System 2.4.2 Forced Vibrations of a Mechanical System 2.4.3 RLC Circuits 2.5 Cauchy-Euler Second Order Differential Equations 2.6 Numerical Methods for Second Order Differential Equations 2.6.1 The Runge-Kutta-Nystrom Method 2.6.2 The Rayleigh-Ritz Finite Difference Methods for Boundary Value Problems 3 Systems of First Order Linear Differential Equations - A Matrix Approach 3.1 Review of Linear Algebra Techniques 3.2 Homogeneous Systems of Differential Equations with Constant Coefficients 3.2.1 Real, Distinct Eigenvalues 3.2.2 Complex Eigenvalues 3.2.3 Repeated Eigenvalues 3.3 Nonhomogeneous Systems of First Order Differential Equations with Constant Coefficients 3.4 Numerical Methods for Systems of First Order Differential Equations 3.4.1 Euler's Method 3.4.2 Fourth Order Runge-Kutta Method 4 Higher Order Linear Differential Equations 4.1 Higher Order Homogeneous Linear DIfferential Equations with Constant Coefficients 4.2 Higher Order Nonhomogeneous Linear Differential Equations 5 Systems of Nonlinear Ordinary Differential Equations 5.1 Stability Properties of Systems of Linear Differential Equations 5.2 Stability Properties of Systems of Nonlinear Differential Equations 5.3 Predator - Prey Interactions and Other Population Models 5.4 Nonlinear Pendulum Dynamics and Other Problems from Mechanics 6 Series Soulutions of Ordinary Differential Equations 6.1 Power Series Solutions of Differential Equations about Ordinary Points 6.2 Power Series Solutions Near a Regular Singular Point 6.3 Bessel's Differential Equations and Bessel Functions 6.4 Legendre's Differential Equation and Legendre Polynomials About This Differential Equations Handbook Electrical Power Systems Engineering 1_1 Per Unit System 1_2 Voltage Drop Calculations 1_3a Load Flow Calculations Theory 1_3b Load Flow Calculations Application 1_4a Least-Cost Power Transformer Sizing - Efficiency 1_4b Least-Cost Power Transformer Sizing - Cost Estimation 1_5a Power System Harmonic Analysis - Introduction 1_5b Power System Harmonic Analysis - Harmonic Interactions 1_6a Power Line Parameters Introduction 1_6b Power Line Parameters Sequence Impedance of Lines 2_1a Power System Faults Introduction 2_1b Power System Faults Application 2_2 Mid-Line Fault Calculations 2_3a Out-of-Step Protection Theory 2_3b Out-of-Step Protection Application 2_4 Introduction Motor Start-up Protection 2_5a DC Motor Protection Modeling 2_5b DC Motor Protection Simulation 3_1a Review of System Transients- Introduction 3_1b Review of System Transients - Transient Overvoltages 3_2a Transformer Energization Theory 3_2b Transformer Energization Modeling 3_2c Transformer Energization Compensation 3_3 Application of Surge Arresters About this E-book Chptr1 Chptr2 Chptr3 Cover Index Table_1_6_1 Table_1_6_2 Table_3_2_1 Techind Toc Finite Element Beginnings 1 Introduction 1_1 Definition and Basic Concepts 1_2 The Process of Discretization 1_2_1 Discrete Systems 1_2_1a Heat Flow 1_2_1b Electrical Networks 1_2_1c Fluid Networks 1_2_1d A Truss Structure 1_2_2 Continous Systems 1_2_2a A Soultion to a 1-D Boundary Value Problem 1_2_3 Comparison to the Finite Difference Method 1_3 Seven Basic Steps of the Finite Element Method 1_3_1 Discretizing the Continuum 1_3_1a Example of an Automatic Solid Mesh Generation 1_3_1b Example of a Manually Created Solid Mesh 1_3_2 Selecting Interpolation Functions 1_3_3 Finding Element Equations 1_3_4 Assembling the Elements 1_3_5 Applying the Boundary Conditions 1_3_6 Solving the System of Equations 1_3_7 Making Additional Computations 1_4 Brief History of the Finite Element Method 2 The Discrete Approach_A Physical Interpretation 2_1 Introduction 2_2 A simple Elastic Spring 2_3 A System of Springs 2_3_1 Step 1 - Discretize the Spring System 2_3_2 Step 2 - Select Interpolation Functions 2_3_3 Step 3 - Find the Element Properties 2_3_4 Step 4 - Assemble the Elements 2_3_5 Step 5 - Apply the Boundary Conditions 2_3_6 Step 6 - Solve the System of Equations 2_3_6a Equivalent Stiffness 2_3_7 Step 7 - Additional Calculations 2_4 Assembling the Elements 2_4_1 An Example Finite Element Mesh 2_4_2 The Assembly Algorithm 2_4_3 Properties of the Assembled Stiffness Matrix 2_5 How to treat Boundary Conditions 2_5_1 The Direct Method 2_5_2 The Payne and Irons Technique 2_5_3 Matrix Partitioning 2_6 1D Discrete Finite Element Algorithm in One Dimension 2_6_1 Application to Other Discrete Systems 2_7 Truss Analysis 2_7_1 Element Stiffness Matrix in Global Coordinates 2_7_2 Stiffness Derivation Using Local Coordinates 2_8 A Finite Element Algorithm for Trusses in Two Dimensions 2_8_1 Truss Algorithm with Discussion 2_8_2 Truss Algorithm without Discussion 3 Introduction to Finite Elements of Elastic Continua 3_1 Introduction 3_2 Continuity of Elements in a Continuum 3_3 Basic Concepts in Three Dimensional Linear Elasticity 3_3_1 The Displacement Field 3_3_2 Strain Components 3_3_3 Stress Components 3_3_4 Constitutive Laws 3_3_5 The Principle of Minimum Potential Energy 3_3_6 Plane Stress and Plane Strain 3_4 A Triangular Element in Plane Stress 3_5 The Direct Method for a Triangular Element 3_5_1 Interpolation of Displacement 3_5_2 Strain-Displacement Equation 3_5_3 Stress-Strain Relationship 3_5_4 Equivalent Forces for a Stress Field 3_5_5 The Stiffness Matrix 3_5_5a Summary of the Direct Method 3_6 The Energy Method for Elastic Elements 3_6_1 The Stiffness Matrix 3_6_2 How to treat Surface Tractions 3_6_3 Final Remarks 3_7 Comparison of the Direct and Energy Methods for Plane Stress 3_8 A Finite Element Code for Plane Strain 3_8_1 Plane Stress Code With Discussion 3_8_2 Plane Stress Code Without Discussion 4 Element Interpolation and Shape Functions 4_1 Introduction 4_2 The Essence of the Finite Element Method 4_2a Typical Problems in Engineering 4_3 Linear Interpolation in One Dimension 4_3_1 jts Piecewise Linear Interpolation 4_3_1 Piecewise Linear Interpolation 4_3_1a jts The Effect of a Finer Mesh 4_3_1a The Effect of a Finer Mesh 4_4 Higher-Order Polynomials in One Dimension 4_4_1 Quadratic Interpolation in One Dimension 4_4_2 Piecewise Quadratic Interpolation 4_4_3 Generalization to Higher Orders 4_5 Derivatives of Shape Functions 4_5_1 Linear Interpolation and Differentiation 4_5_2 Quadratic Interpolation and Differentiation 4_5_3 Continuity Requirements 4_6 Polynomials in two Dimensions 4_6_1 A Linear Triangular Element 4_6_2 A Four Node Rectangular Element 4_6_3 A Specialized Rectangular Element 4_7_1a_Piecewise_Approximati on_Using_Lagrange_Polynomial s 4_7_1_1D_Lagrangian_Shape_Functions 4_7_2a Condensation of Internal Nodes 4_7_2_2D_Lagrangian_Shape_Functions 4_7_3 2-D Serendipity Shape Functions 4_7_3a Serendipity Shape Functions for a Linear Element 4_7_3b Serendipity Shape Functions for a Quadratic Element 4_7_3c_Serendipity_Shape_Fun ctions_for_a_Cubic_Element 4_8 Final Remarks 5 Mapped Elements 5_1 Introduction 5_2 Mapping in One Dimension 5_2_1 Differentiation snd Integration 5_2_1a Newton-Cotes Quadrature 5_2_1b Gaussian Quadrature 5_2_1c Summary 5_2_1s Element Length in Symbolic Form 5_3 Mapping in Two Dimensions 5_4 Evaluation of Element Equations 5_4_1 Transformation of Derivatives 5_4_1a Linear Mapped Elements 5_4_1b Quadratic Mapped Elements 5_4_1c Cubic Mapped Elements 5_4_2 The Area Integral and Numerical Integration 5_4_2a Integration of Mapped Quadratic Elements 5_4_2d1 Transformation of an Element of Area 5_4_3 Integration Along Element Boundaries 5_5 Shape Functions Along Element Boundaries 5_5_1 Reduction to One Dimension on Boundaries 5_5_2 Evaluating a Distributed Edge Load 5_6 Finite Element Code Using Isoparametric Plane Stress Elements 5_6_1 Linear Isoparametric Plane Stress Elements 5_6_1 5_6_2 Quadratic Isoparametric Plane Stress Elements 5_6_2 6 The Method of Weighted Residuals 6_1 Introduction 6_2 Overview of Residual Methods 6_2_1 Problem Definition 6_2_2 Approximate Solution Using Trial Functions 6_2_2a Point Collacation 6_2_2b Subdomain Collcation 6_2_2c Galerkin's Method 6_2_3 Comparison of the Three Methods 6_3 Applying Galerkin's Method to Finite Elements 6_3_1 One Dimension Integration by Parts 6_3_2 Finite Element Code in One Dimension 6_3_3 Two Dimensions Green's Theorem 6_4 Finite Element Applications 6_4_1 Laplace's Equations in a Circular Disk 6_4_1a Linear Finite Element Code for Laplace's Equation 6_4_2 Laplace's Equation in a Rectangular Region 6_4_2a Quadratic Finite Element Code for Laplace;s Equation 6_4_2b Detail of Exact Solution 6_5 Concluding Remarks Mathcad Prime Tutorials with Physics Examples 2_1basic 2_2basic 2_3basic 3_1varb 3_2varb 3_3varb 4_1solve 4_2solve 4_3solve 4_4solve 4_5solve 5_1graph 5_2graph 5_3graph 6_1what 6_2what 6_3what 6_4what 7_1data 7_2data 7_3data 8_final Miscellaneous Worksheets Analyzing Process Capabilities Applying the Momentum Equation to Determine Water Depth between Bridge Piers Balancing the pH Balance and Composition of Two Chemical Soultions Bearing Capacity and Maximum Load of a Pier Calculating Fault Current Magnitude in PTC Mathcad Calculating Force on a Truss Connection Joint Calculating the Tensile Stress and Tensile Forces in the Bolt of a Flange Pipe Calculating Volume of a Pressure Vessel Calculating Water Amount for Borehole Drilling Choosing a Cam-Type Cluth to Drive a Centrifugal Pump Comparing Air Pressure and Elevation for Air Volume Calculations Complex Numbers in PTC Mathcad Converting Nonlinear Systems to Linear Ones Cubic Spline Interpolation D3Q3_Mod Determining Suction Lift Pump Height Using Solve Blocks Developing IDF Curves from Rainfall Data Differential Algebraic Equations in PTC Mathcad Eigenvalues and Eigenvectors in PTC Mathcad Ergodicity in a Harmonic Oscillator Example of Solving a System of Equations with Units Example of Using Laplace Transforms to Solve an ODE Example of Using Symbolic Math to Solve an ODE Financial Risk Management in PTC Mathcad Finding Channel Height Channel Width and Velocity of Water Finding the Actual Force and Brake Capacity of a Long-Shoe Internal Drum Brake Finding the Shear Force and Bending Moment Along a Beam Finite vs Infinite Life and Fatigue Failure for a Steel Object Fitting Hyperbolic Data Gaussian Probability Distribution in PTC Mathcad Gauss_Newton Nonlinear Regression Generating Polar Histograms in PTC Mathcad Getting Started with Mathcad Inventory Control Example in PTC Mathcad Linear and Angular Momentum of Three Small Balls Load Flow Calculations Logistic Map and Ideal Random Number Generator Manufacturing Perfomance Curves in PTC Mathcad Measuring Traffic Flow and EAL for Vehicles Modeling of SAW Delay Lines modelling the ocean Monte Carlo Simulation of the Streeter Phelps Equation Natural Math and Units Numeric and Symbolic Variables in PTC Mathcad - Undefining a variable Numeric vs. Smbolic Representations in PTC Mathcad Performing a Weighted Fit in PTC Mathcad Planar Regression in PTC Mathcad Plotting Frequency Distribution Data in PTC Mathcad Preparing Time Series for Data Analysis Preventing System Failures with Reliability Testing for Pump Systems Random Triangles in the Unit Square Random Walks in PTC Mathcad Response Surface Modeling in PTC Mathcad Risk Probability and Flood Proofing a Bridge Over a River RLC Circuit Analysis Seeded Iteration in PTC Mathcad Solving Coupled ODEs in PTC Mathcad Solving Systems of Equations in PTC Mathcad Using the Find Function The Weibull Distribution Function in Reliability Statistics Theory of the Capacitor revised Three Phase Power System in PTC Mathcad Tracking the Development of a Storm Using Cubic Splines to Determine Characteristics and Efficiency of a Pump Using Henrys Law and Solve Blocks in Chemistry and Environmental Engineering Using the Finite Element Method on Truss Structures Visualisation of Typical Wellbore Survey Data Programming in PTC Mathcad 3.0 1.0 What is Programming in PTC Mathcad 2.1 Functions Definitions 2.2 Recursively Defined Functions 2.4 If 2.5 Boolean Operators 3.0 The Include Worksheet Operation 4.1 Introduction 4.10 Error Trapping 4.11 Error Messages 4.12 Programs and Symbolic Computation 4.2 The Program Operator 4.3 Local Assignments 4.4 The if and else Operators 4.5 The for Loop 4.6 The while Loop 4.7 The continue and break Operators 4.8 The return Operator 4.9 Type Checking 5.1 Dynamically Linked Libraries 6.10 Local Functions 6.11 Periodic Extensions 6.12 Working with Strings 6.2 The Greatest Common Divisor 6.3 Pi 6.4 The 3N + 1 Problem (Recursion) 6.6 Interesting (and Useful) Functions 6.7 The Convex Hull 6.8 An Adaptive Quadrature Algorithm 6.9 Set Theory Topics in Electrical Engineering 10_Delta_Modulation 11.1_ZTransform_and_Inverse_Transfo rm 11.2_Linear_ConstantCoefficient_Difference_Equation s 12_Algebraic_Codes 13.1_Analog_and_Digital_Lowp ass_Butterworth_Filter 13.2_Analog_Elliptic_Filter_Desi gn 13.3_Digital_Elliptic_Filter_Desig n 14_Chebyshev_Polynomials 15_FIR_Filter_Design_by_Wind owing 1_Field_Patterns_of_a_Uniform _Linear_Antenna_Array 2.1_1-D_Waveguides__Striplines 2.2_2-D_Waveguides 2.3_3-D_Resonators 2.4_Circular_Waveguides__Coaxial_Lines 3.1_Impedance_as_a_Function_ of_z,_w 3.2_Reflection_Coefficient_Calc ulations 3.3_The_Smith_Chart 4_Network_Analysis_Using_an_ Admittance_Matrix 5.1_Bode_Plots_and_Nichols_C harts 5.2_Root-Locus_Technique 5.3_Polar_Plots_and_Nyquist_Pl ots 6_Two-Port_Networks 7_American_Wire_Gauge_Table 8_Convolution_and_Deconvoluti on 9_Digitizing_a_Signal About_Topics_in_Electrical_Engi neering
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