PSPICE SIMULATION OF SINGLE PHASE SHUNT ACTIVE HARMONIC FILTER POWER

 

PSpice Simulation - Parametric Sweep

PSPICE SIMULATION - PARAMETRIC SWEEP ※ 

Parametric Sweep conducts simulation by changing element values ​​set as variables in the circuit. This has been covered in the previous DC sweep, and this is because Parametric Sweep can be implemented not only by sweeping variables arbitrarily set by the user, but also by changing the values ​​of used elements. 

 1. Circuit diagram

After writing, apply vcc and vee through the vcc element of place power, and give the name of the out node through place net alias. 

 One thing to note here is that the value of resistance R2 must be entered as {Rvar}. This means that it will have a value as a variable called Rvar. 

 Also, pay attention to the input terminal sign of LM324. After placing the element, you must press the V key to invert it up and down. 

 Now we need to set the value of the variable Rvar. 

The value of the variable uses the element that appears when you search for PARAM in the place part.

After placing the element, double-click on the element to modify its properties.

 

If you double-click the upper left corner of the table that appears, the property will change from horizontal alignment to vertical alignment.

Click New Row at the top left.

Enter Rvar corresponding to the variable name as the new property and 200 as the desired initial value. Click Apply to continue adding new rows, and click OK to finish. When finished, press OK. Place the mouse cursor on the added value of Rvar, right-click, and select display.

Select Name and Value from the properties that appear.

Press OK, right-click the open tab to save it, then right-click again to close it.

When you return to the circuit diagram, you can see that the initial values ​​of the variables have been set.

2. Simulation settings

Select AC Sweep/Noise. It varies from 10 to 100 kHz and has 100 points per section.

Check Parametric Sweep in Options on the left. 

 Since the value you want to change is a variable called Rvar set by the user, select Global Parameter and write Rvar in the name. The value is increased by 200 from 200 to 1k.

If you do not want to change the value linearly but want to change it to specific values, select Sweep type as Value list at the bottom instead of Linear and write the values. Values ​​can be separated by spaces or commas. ex) 5m, 10m, ... Once the setup is complete, place a dB scale voltage probe as in the previous AC sweep post.

3. Execution result

 If you run the simulation, you can get the following results.

You can see that the area of ​​the pass band is different depending on each resistance value. 

 Therefore, for analysis, let's find the area of ​​the pass band that is 3dB lower than the maximum value. Since it is analyzed using multiple results, it must be interpreted through the performance analysis discussed earlier. 

 When performing performance analysis using the methods discussed above, there are times when it does not execute due to errors. 

 Therefore, this time we will proceed with performance analysis in a slightly different way.

First, click the Perfromance analysis icon on the toolbar at the top of the simulation window.

Then, a new plot is created at the top, and you can confirm that it is selected through SEL>>.

 Select Trace > Add trace from the menu at the top of the simulation window.

First, select Bandwidth_Bandpass_3dB(1) from the functions on the right ,

 and then select V(out) from the variables on the left.

Then, you can check the size of the pass band according to the Rvar value.

Please keep in mind that performance analysis is used when interpreting multiple results.

PSPICE SIMULATION MODIFIED SINE WAVE INVERTER SETUP CONFIGURATION AND WAVEFORM

 

Pspice Simulation Power Supply with Current Type Single-Ended Flyback Output with UC3845

 

FLYBACK CONVERTER

The single-ended flyback switching power supply has been widely used in the power supply of automatic control and intelligent instrument because of its advantages of simple structure and few components . The duty cycle of the power MOSFET is regulated by pulse width modulation (PWM) technology to stabilize the output voltage. This circuit used a high-performance integrated control chip UC3845 as a pulse width modulation device. Its main features are an internal oscillator, high-precision error comparator, cycle-by-cycle current sampling-comparison, low start-up current, high-current totem pole output, etc., which are ideal devices for driving MOSFETs

VYSOKÉ UČENÍ TECHNICKÉ V BRNĚ BRNO UNIVERSITY OF TECHNOLOGY FAKULTA ELEKTROTECHNIKY A KOMUNIKAČNÍCH TECHNOLOGIÍ FACULTY OF ELECTRICAL ENGINEERING AND COMMUNICATION ÚSTAV RADIOELEKTRONIKY DEPARTMENT OF RADIOENGINEERING -DC-DC MĚNIČ PRO MATRIX BEAM- MODUL DC-DC CONVERTER FOR MATRIX BEAM MODULE DIPLOMOVÁ PRÁCE MASTER'S THESIS AUTOR PRÁCE AUTHOR Bc. Roman Sikora

 

VYSOKÉ UČENÍ TECHNICKÉ V BRNĚ BRNO UNIVERSITY OF TECHNOLOGY FAKULTA ELEKTROTECHNIKY A KOMUNIKAČNÍCH 

TECHNOLOGIÍ FACULTY OF ELECTRICAL ENGINEERING AND COMMUNICATION ÚSTAV

 RADIOELEKTRONIKY DEPARTMENT OF RADIOENGINEERING 

DC-DC MĚNIČ PRO MATRIX BEAM MODUL 

 ABSTRACT 

The master thesis deals with the development of buck-boost DC-DC converter which supplies matrix beam module. The design is focused on testing two-phase boost converter and three channel buck converter manufactured by NXP Semiconductors. Part of the design is implementation of microcontroller for converter control and communication with computer. Part of the thesis is also to design user interface on Windows platform for easy system configuration. Next thing the thesis deals with is designing load for DC-DC converter that is variable and can make different current consumption. One part of this thesis is focused to achieve the lowest conducted emissions and to maximize conducted immunity. Part of this project is production of a prototype and prototype testing.

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https://www.vut.cz/www_base/zav_prace_soubor_verejne.php?file_id=208360