![]() ![]() * Analysis of Sequential Circuits * Excitation Tables for Flip Flops * Finite State Machine Diagram * Mealy Finite State Machine * Moore Finite State Machine * Need for State Machines * State Diagrams * State Encoding Techniques * State Machine * State Minimization * VHDL Coding of FSM * JK flipflop State Machine * Metastability measurement setup * Metastability Synchronizer * Detection of Static Hazards * Dynamic Hazards * Effects of Hazards * Elimination of Static Hazards * Static Hazards ![]() * UART Transmitter Design * UART Receiver Design * Traffic Light Controller * Simple Traffic Controller * Serial Adder * Sequential Counters JKFF * Sequential Counters DFF * Sequential Counters * Sequence Generator * Sequence Detector * Lift Controller * Analysis of Asynchronous Sequential Machines * Asynchronous FSM * Design of Asynchronous Sequential Machine * Design Procedure for Asynchronous Sequential Circuits * Essential Hazards * Hazardfree circuit * Modes of Asynchronous Sequential Machines ![]() * ASM chart 2 bit up down counter * ASM chart for signal generator * ASM charts * ASM Chart Tool for Sequential Circuit Design * Design with Multiplexers * adjustable negative voltage regulator ics * current booster * dual power supply * low drop out voltage regulators * series regulator using op amp * three terminal adjustable voltage regulator ics * three terminal fixed voltage regulator ics * voltage regulators ics * asymmetrical inverting schmitt trigger * inverting schmitt trigger * non inverting schmitt trigger * modified precision full wave rectifier * non saturated type precision half wave rectifier * precision full wave rectifier * saturating type precision hwr * difference integral * non inverting integrator * practical integrator * summing integrator * practical differentiator * summing differentiator * comparator as a duty cycle controller * comparator as a function generator * comparator ic lm 311 * inverting comparator * non inverting comparator * voltage controlled oscillator * window comparator * asymmetrical square wave generator * bistable multivibrators * monostable multivibrator * sawtooth waveform generator * triangular waveform generator * binary weighted resistor dac * counter type adc * dual slope type adc * flash type adc * r 2r ladder dac * successive approximation type adc However, the waveforms of practical inverters are non-sinusoidal and contain certain harmonics. The output voltage waveforms of ideal inverters should be sinusoidal. ![]() The function of an inverter is to change a dc input voltage to a symmetric ac output voltage of desired magnitude and frequency. The DC output of the battery is bucked or boosted according to the requirement and then converted into AC using a DC-AC inverter. The main source of electrical power is the battery which is a DC source. In figure above it can be seen that the traction motor requires AC input. Figure below shows the Configuration of Electric Vehicle. The input voltage depends on the design and purpose of the inverter. Figure below shows Basic DC-AC Inverter Block Diagram.Ī typical power inverter device or circuit requires a relatively stable DC power source capable of supplying enough current for the intended power demands of the system. The inverter does not produce any power the power is provided by the DC source. The input voltageÂ, output voltage and frequency, and overall power handling depend on the design of the specific device or circuitry. Static inverters do not use moving parts in the conversion process. A power inverter can be entirely electronic or may be a combination of mechanical effects (such as a rotary apparatus) and electronic circuitry. A power inverter, or inverter, is an electronic device or circuitry that changes direct current (DC) to alternating current (AC). ![]()
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