Inhaltsverzeichnis

• BEGINN
• ● Preface
• Chapter 1 ● Introduction
• 1.1 ● Why simulation?
• 1.2 ● Electronic simulation
• 1.3 ● SPICE modelling of electronic circuits
• 1.4 ● The TINA program
• Chapter 2 ● TINA Versions
• 2.1 ● Overview
• 2.2 ● Version features
• 2.3 ● Options
• 2.4 ● Supplementary hardware
• Chapter 3 ● TINA Installation Procedure
• 3.1 ● Hardware and software requirements
• 3.2 ● Installation
• 3.3 ● Installing the hardware key (dongle) version of TINA
• 3.4 ● Authorisation of the software protected version of TINA
• Chapter 4 ● Getting Started – Simulating Simple Circuits
• 4.1 ● The Schematic Editor
• 4.2 ● Simulation 1 – Series and parallel resistors
• 4.3 ● Simulation 2 – Resistor – capacitor circuit
• 4.4 ● Simulation 3 – Resistor – inductor-capacitor circuit
• 4.5 ● Simulation 4 – Power consumption – using a power meter
• 4.6 ● Simulation 5 – Voltage across components – using voltmeters
• 4.7 ● Simulation 6 – Current through components using Ampere Meters
• 4.8 ● Simulation 7 – Impedance measurement using the Impedance Meter
• 4.9 ● Simulation 8 – Resistance measurement using the Ohmmeter
• 4.10 ● Simulation 9 – Plotting voltage across components using an Oscilloscope component
• 4.11 ● Simulation 10 – Measuring frequency using a frequency meter
• 4.12 ● Simulation 11 – AC circuit analysis I
• 4.13 ● Simulation 12 – AC circuit analysis II
• 4.14 ● Simulation 13 – AC circuit analysis III
• 4.15 ● Simulation 14 – Thevenin†™s Theorem - AC circuit analysis
• 4.16 ● Simulation 15 – Norton†™s Theorem - AC circuit analysis
• 4.17 ● 3-Phase circuits
• 4.18 ● Mutual inductance
• Chapter 5 ● Diode Circuit Design and Simulation
• 5.1 ● Simulation 1 – Simple diode circuit
• 5.2 ● Simulation 2 – Half-wave rectifier circuit
• 5.3 ● Simulation 3 – Half-wave rectifier circuit with transformer
• 5.4 ● Simulation 4 – Full-wave rectifier circuit with center-tapped transformer
• 5.5 ● Simulation 5 – Full-wave bridge rectifier circuit with transformer
• 5.6 ● Simulation 6 – Diode clamper circuit
• 5.7 ● Simulation 7 – Zener diode characteristics
• 5.8 ● Simulation 8 – Zener diode voltage regulator
• 5.9 ● Simulation 9 – Zener diode symmetrical voltage limiter
• 5.10 ● Simulation 10 – Voltage tripler circuit
• Chapter 6 ● Transistor Circuit Design and Simulation
• 6.1 ● Simulation 1 – Bipolar transistor characteristics
• 6.2 ● Simulation 2 – Common emitter transistor amplifier - Analysis
• 6.3 ● Simulation 3 – Common emitter transistor amplifier - Design
• 6.4 ● Simulation 4 – Multi-stage common emitter transistor amplifier – Using subcircuits in TINA
• 6.5 ● The Netlist
• 6.6 ● Simulation 5 – BJT transistor Colpitts oscillator
• 6.7 ● Transistor as a two port network
• 6.8 ● Simulation 6 – JFET transistor common source amplifier
• 6.9 ● Simulation 7 – JFET transistor characteristic curves
• 6.10 ● Simulation 8 – BJT Transistor switch
• 6.11 ● Thyristors and triacs
• 6.12 ● Audio power amplifiers
• Chapter 7 ● Operational Amplifier Circuit Design and Simulation
• 7.1 ● Key characteristics
• 7.2 ● Operational amplifier circuits
• 7.3 ● Simulation 1 – Inverting amplifier
• 7.4 ● Simulation 2 – Summing amplifier
• 7.5 ● Simulation 3 – Voltage integrating amplifier
• 7.6 ● Simulation 4 – Half-wave rectifier circuit
• 7.7 ● The Design Tool
• 7.8 ● Optimisation
• 7.9 ● Sinusoidal oscillators
• 7.10 ● Square wave generators
• Chapter 8 ● Filter Circuit Design and Simulation
• 8.1 ● TINA filters
• 8.2 ● Simulation 1 – Designing a 2nd order low-pass active filter
• 8.3 ● Simulation 2 – Designing a higher-order low-pass active filter
• 8.4 ● Simulation 3 – Designing a high-pass active filter
• 8.5 ● Simulation 4 – Designing a band-pass active filter
• 8.6 ● Simulation 5 – Designing a low-pass passive filter
• Chapter 9 ● Digital Logic Circuit Design and Simulation
• 9.1 ● Digital logic simulation using TINA
• 9.2 ● Simulation 1 – Simple AND gate
• 9.3 ● Simulation 2 – Half adder using gates
• 9.4 ● Simulation 3 – 2-bit synchronous counter
• 9.5 ● Simulation 4 – 7-segment LED display
• 9.6 ● Simulation 5 – 4-bit binary counter with logic indicators
• 9.7 ● Simulation 6 – 4-bit decade counter with 7-segment display
• 9.8 ● Simulation 7 – 8-bit decade counter with two 7-segment displays
• 9.9 ● Simulation 8 – 4-bit decade counter and 7-segment display – Using a 4-bit Data Generator
• 9.10 ● Simulation 9 – Creating a full adder – using a MACRO
• 9.11 ● Using Hardware Description Languages (HDLs)
• 9.12 ● Using Verilog simulation in TINA to analyse digital circuits
• Chapter 10 ● Logic Design Tool
• Chapter 11 ● Simulating Microcontrollers
• 11.1 ● Overview
• 11.2 ● Using the Flowchart editor
• 11.3 ● Using assembly programming
• 11.4 ● Using C programming
• 11.5 ● Memory devices
• Chapter 12 ● Ladder Logic Circuits
• 12.1 ● Overview
• 12.2 ● Simulation 1 – Ladder logic with a light and motor
• 12.3 ● Ladder logic components as digital logic components
• 12.4 ● Latching circuit
• Chapter 13 ● Switching-Mode Power Supply Circuits (SMPS)
• 13.1 ● Overview
• 13.2 ● Simulation 1 – TPS61031 SMPS circuit
• Chapter 14 ● Printed Circuit Board (PCB) Design
• 14.1 ● Overview
• 14.2 ● Bipolar transistor multivibrator circuit project
• 14.2.1 ● The design
• Chapter 15 ● PCB Design Techniques
• 15.1 ● Overview
• 15.2 ● Creating Buses in the Schematic Editor and the PCB Designer of TINA
• 15.3 ● Multiple units in the same package
• 15.4 ● Power supply of logic components
• 15.5 ● Repeating circuit blocks (using the Copy Macro function)
• 15.6 ● Creating a Two-Layer, Double-Sided, Surface-Mount Technology Board
• 15.7 ● Creating PCB components
• Chapter 16 ● Making Schematic Symbols and Footprints
• 16.1 ● Overview
• 16.2 ● Example
• 16.3 ● Using the IC wizard in Schematic Symbol editor
• 16.4 ● Using the Footprint editor
• 16.5 ● IC Wizard in the Footprint Editor
• 16.6 ● Adding Public PCB Footprints to TINA
• 16.7 ● Adding Public 3D Footprint models to TINA
• Chapter 17 ● Using TINACloud
• 17.1 ● Overview
• 17.2 ● Starting to use TINACloud
• 17.3 ● Example simulation
• 17.4 ● Example PCB design
• 17.5 ● Sharing your TINA schematic
• Chapter 18 ● Other Useful Tools
• 18.1 ● Overview
• 18.2 ● 3D Breadboard
• 18.3 ● Stress (Smoke) analysis
• 18.4 ● Electric Rules Check (ERC)
• 18.5 ● Serial monitor
• 18.6 ● Component explorer
• 18.7 ● Find component
• 18.8 ● Protect circuit
• 18.9 ● Export
• 18.10 ● Import
• 18.11 ● Fourier series
• 18.12 ● Fourier spectrum
• 18.13 ● Noise analysis
• 18.14 ● Power dissipation analysis
• 18.15 ● Interpreter
• 18.16 ● DC Temperature analysis
• 18.17 ● The parameter extractor
• 18.18 ● Finite State Machine Editor
• Chapter 19 ● The Library Manager
• Chapter 20 ● Field-Programmable Gate Arrays (FPGA)
• 20.1 ● Overview
• 20.2 ● Programming FPGA Boards with Schematic Design Entry using TINA – Example 1
• 20.3 ● Programming FPGA Boards with Schematic Design Entry using TINA – Example 2
• 20.4 ● Programming FPGA Boards in VHDL with TINA
• 20.5 ● Programming FPGA Boards in Verilog with TINACloud
• 20.6 ● Storing the program in non-volatile memory of Basys 3 board
• 20.7 ● Seconds counter on the 7-segment 4-digit Basys 3 FPGA board using TINA with VHDL
• 20.8 ● Pushbutton counter on the 7-segment 4-digit Basys 3 FPGA board using TINA with VHDL
• Chapter 21 ● Additional Information
• 21.1 ● TINA website
• 21.2 ● TINA-TI
• 21.3 ● Other useful websites
• 21.4 ● TINA Help files
• ● Epilogue
• ● Index