A solar inverter helps in converting the direct current into alternate current with the help of solar power. Direct power is that power which runs in one direction inside the circuit and helps in supplying current when there is no electricity. A common topology for DC-AC power converter circuits uses a pair of transistors to switch DC current through the center-tapped winding of a step-up transformer, like this: In order for this form of circuit to function properly, the transistor “firing” signals must be precisely synchronized to ensure the two are never turned on simultaneously.
The inverter is truly the nucleus of all digital designs. Once its operation and properties are clearly understood, designing more intricate structures such as NAND gates, adders, multipliers, and microprocessors is greatly simplified. The electrical behavior of these complex circuits can be almost completely derived by extrapolating the results obtained for inverters.
The analysis of inverters can be extended to explain the behavior of more complex gates such as NAND, NOR, or XOR, which in turn form the building blocks for modules such as multipliers and processors. In this chapter, we focus on one single incarnation of the inverter gate, being the static CMOS inverter — or the CMOS inverter, in short. This is certainly the most popular at present and therefore deserves our special attention.
Principle of Operation
The logic symbol and truth table of ideal inverter is shown in figure given below. Here A is the input and B is the inverted output represented by their node voltages. Using positive logic, the Boolean value of logic 1 is represented by Vdd and logic 0 is represented by 0. Vth is the inverter threshold voltage, which is Vdd /2, where Vdd is the output voltage.
The output is switched from 0 to Vdd when input is less than Vth. So, for 0<Vin<Vth output is equal to logic 0 input and Vth<Vin< Vdd is equal to logic 1 input for inverter.
The characteristics shown in the figure are ideal. The generalized circuit structure of an nMOS inverter is shown in the figure below.
From the given figure, we can see that the input voltage of inverter is equal to the gate to source voltage of nMOS transistor and output voltage of inverter is equal to drain to source voltage of nMOS transistor. The source to substrate voltage of nMOS is also called driver for transistor which is grounded; so VSS = 0. The output node is connected with a lumped capacitance used for VTC.
Resistive Load Inverter
The basic structure of a resistive load inverter is shown in the figure given below. Here, enhancement type nMOS acts as the driver transistor. The load consists of a simple linear resistor RL. The power supply of the circuit is VDD and the drain current ID is equal to the load current IR.
Circuit Operation
When the input of the driver transistor is less than threshold voltage VTH (Vin < VTH), driver transistor is in the cut – off region and does not conduct any current. So, the voltage drop across the load resistor is ZERO and output voltage is equal to the VDD. Now, when the input voltage increases further, driver transistor will start conducting the non-zero current and nMOS goes in saturation region.
Mathematically,
$$I_{D} = frac{K_{n}}{2}left [ V_{GS}-V_{TO} right ]^{2}$$
Increasing the input voltage further, driver transistor will enter into the linear region and output of the driver transistor decreases.
$$I_{D} = frac{K_{n}}{2}2left [ V_{GS}-V_{TO} right ]V_{DS}-V_{DS}^{2}$$
VTC of the resistive load inverter, shown below, indicates the operating mode of driver transistor and voltage points.
Inverter with N type MOSFET Load
The main advantage of using MOSFET as load device is that the silicon area occupied by the transistor is smaller than the area occupied by the resistive load. Here, MOSFET is active load and inverter with active load gives a better performance than the inverter with resistive load.
Enhancement Load NMOS
Two inverters with enhancement-type load device are shown in the figure. Load transistor can be operated either, in saturation region or in linear region, depending on the bias voltage applied to its gate terminal. The saturated enhancement load inverter is shown in the fig. (a). It requires a single voltage supply and simple fabrication process and so VOH is limited to the VDD − VT.
The linear enhancement load inverter is shown in the fig. (b). It always operates in linear region; so VOH level is equal to VDD.
Linear load inverter has higher noise margin compared to the saturated enhancement inverter. But, the disadvantage of linear enhancement inverter is, it requires two separate power supply and both the circuits suffer from high power dissipation. Therefore, enhancement inverters are not used in any large-scale digital applications.
Depletion Load NMOS
Drawbacks of the enhancement load inverter can be overcome by using depletion load inverter. Compared to enhancement load inverter, depletion load inverter requires few more fabrication steps for channel implant to adjust the threshold voltage of load.
The advantages of the depletion load inverter are - sharp VTC transition, better noise margin, single power supply and smaller overall layout area.
As shown in the figure, the gate and source terminal of load are connected; So, VGS = 0. Thus, the threshold voltage of the load is negative. Hence,
$$V_{GS,load}> V_{T,load}$$ is satisfied
Therefore, load device always has a conduction channel regardless of input and output voltage level.
When the load transistor is in saturation region, the load current is given by
$$I_{D,load} = frac{K_{n,load}}{2}left [ -V_{T,load}left ( V_{out} right ) right ]^{2}$$
When the load transistor is in linear region, the load current is given by
$$I_{D,load} = frac{K_{n,load}}{2}left [ 2left | V_{T,load}left ( V_{out} right ) right |.left ( V_{DD}-V_{out} right )-left ( V_{DD}-V_{out} right )^{2} right ]$$
The voltage transfer characteristics of the depletion load inverter is shown in the figure given below −
CMOS Inverter – Circuit, Operation and Description
The CMOS inverter circuit is shown in the figure. Here, nMOS and pMOS transistors work as driver transistors; when one transistor is ON, other is OFF.
This configuration is called complementary MOS (CMOS). The input is connected to the gate terminal of both the transistors such that both can be driven directly with input voltages. Substrate of the nMOS is connected to the ground and substrate of the pMOS is connected to the power supply, VDD.
So VSB = 0 for both the transistors.
$$V_{GS,n}=V_{in}$$
$$V_{DS,n}=V_{out}$$
And,
$$V_{GS,p}=V_{in}-V_{DD}$$
$$V_{DS,p}=V_{out}-V_{DD}$$
When the input of nMOS is smaller than the threshold voltage (Vin < VTO,n), the nMOS is cut – off and pMOS is in linear region. So, the drain current of both the transistors is zero.
$$I_{D,n}=I_{D,p}=0$$
Therefore, the output voltage VOH is equal to the supply voltage.
$$V_{out}=V_{OH}=V_{DD}$$
When the input voltage is greater than the VDD + VTO,p, the pMOS transistor is in the cutoff region and the nMOS is in the linear region, so the drain current of both the transistors is zero.
$$I_{D,n}=I_{D,p}=0$$
Therefore, the output voltage VOL is equal to zero.
$$V_{out}=V_{OL}=0$$
The nMOS operates in the saturation region if Vin > VTO and if following conditions are satisfied.
$$V_{DS,n}geq V_{GS,n}-V_{TO,n} $$
$$V_{out}geq V_{in}-V_{TO,n} $$
The pMOS operates in the saturation region if Vin < VDD + VTO,p and if following conditions are satisfied.
$$V_{DS,p}leq V_{GS,p}-V_{TO,p} $$
$$V_{out}leq V_{in}-V_{TO,p} $$
For different value of input voltages, the operating regions are listed below for both transistors.
Region | Vin | Vout | nMOS | pMOS |
---|---|---|---|---|
A | < VTO, n | VOH | Cut – off | Linear |
B | VIL | High ≈ VOH | Saturation | Linear |
C | Vth | Vth | Saturation | Saturation |
D | VIH | Low ≈ VOL | Linear | Saturation |
E | > (VDD + VTO, p) | VOL | Linear | Cut – off |
The VTC of CMOS is shown in the figure below −
Single-Phase PWM Inverter
This example shows the operation of a single-phase PWM inverter.
Description
The system consists of two independent circuits illustrating single-phase PWM voltage-sourced inverters.
The Half-Bridge Converter block and the Full-Bridge converter block are modeling simplified model of an IGBT/Diode pair where the forward voltages of the forced-commutated device and diode are ignored.
The converters are controlled in open loop with the PWM Generator blocks. The two circuits use the same DC voltage (Vdc = 400V), carrier frequency (1620 Hz) and modulation index (m = 0.8).
In order to allow further signal processing, signals displayed on the Scope block are stored in a variable named ScopeDataForFFT, in structure with time format.
Simulation
Run the simulation and observe the current into the loads and the voltage generated by the PWM inverters.
Once the simulation is completed, open the Powergui and select FFT Analysis to display the 0 - 5000 Hz frequency spectrum of signals saved in the ScopeDataForFFT structure. The FFT will be performed on a 2-cycle window starting at t = 0.07 - 2/60 (last 2 cycles of recording). Click on Display and observe the frequency spectrum of last 2 cycles.
The fundamental component of V inverter is displayed above the spectrum window. Compare the magnitude of the fundamental component of the inverter voltage with the theoretical values given in the circuit. Compare also the harmonic contents in the inverter voltage.
The half-bridge inverter generates a bipolar voltage (-200V or +200V) . Harmonics occur around the carrier frequency (1620 Hz +- k*60 Hz), with a maximum of 103% at 1620 Hz.
The full-bridge inverter generates a monopolar voltage varying between 0 and +400V for one half cycle and then between 0 and -400V for the next half cycle. For the same DC voltage and modulation index, the fundamental component magnitude is twice the value obtained with the half-bridge. Harmonics generated by the full-bridge are lower and they appear at twice the carrier frequency (maximum of 40% at 2*1620+-60 Hz). As a result, the current obtained with the full-bridge is smoother.