Solving for Phasor to Complex Units in a Circuit: V21, V13, V34, V24 Calculation

In summary: V21=-V12=-9V21=-V12=-9In summary, when dealing with complex numbers in phasor form, it is important to keep track of the magnitude and phase angle, as well as the direction of potential changes in the circuit. By using the Pythagorean theorem and the Euler identity, the resulting complex numbers can be converted back into phasor form.
  • #1
DODGEVIPER13
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Homework Statement


Several of the voltages associated with a certain circuit are given by V12=9∠30° V, V32=3∠132° V, V14=2∠10° V. Determine V21, V13, V34, and V24.


Homework Equations





The Attempt at a Solution


I am just using this problem as an example as I have no idea how to go from phasor to complex. So V13=V12+V32=9∠30°+3∠132°=? I don't really know here I can only imagine Magnitude*cos(θ)=Real and Magnitude*sin(θ)=imaginary I know this but how do I ultilize these beacuse everything I have done does not work?
 
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  • #2
Your first example is magnitude 9, phase angle 30 degrees. So the complex number is 9 x [cos(30) + j sin(30)]; this is what you have proposed. Make sure your calculator/computer is set to degrees, or else convert them to radians.

The alternative expression (in radians) may be more useful: use the Euler identity and write it as
9 exp(j*30/360*2pi).Here is an example: http://people.clarkson.edu/~jsvoboda/eta/phasors/AddPhasors10.html
 
  • #3
Ok thanks man
 
  • #4
hey for V13 I get 5.865+j6.798 V
 
  • #5
back in phasor I get 8.978∠49.21°
 
  • #6
V21=V32+V13=3.936+j9.096
 
  • #7
V34=V13+V14=7.834+j7.145 and V24=V32+V34=5.906+j9.443
 
  • #8
DODGEVIPER13 said:
V21=V32+V13=3.936+j9.096

As a reality check, note that you are given a value for V12. Shouldn't V21 = -V12?
 
  • #9
oh heh so it should be V21=-9∠30° V
 
  • #10
Also are the rest of my answers correct?
 
  • #11
DODGEVIPER13 said:
oh heh so it should be V21=-9∠30° V

Right. So if the method you employed previously doesn't result in that value, something may be amiss with your method. Better check into that.

Note that it's common practice to roll the "negative" into the angle in order to leave the magnitude positive. Add + or - 180° to the angle.
 
  • #12
To keep things straight I'd suggest creating a little circuit fragment containing the "known" points and their given potential differences. Something like:

attachment.php?attachmentid=61989&stc=1&d=1379638976.gif


The voltage supply polarities reflect the subscript convention, namely Vab would be the potential at a with respect to b, so that by convention a is where your meter's "+" lead would go and b would be where the "-" lead would go, if you were to make the measurement Vab. The actual values assigned to the supplies may be positive or negative depending upon what you're given.

Then, to find any potential difference between points, perform the "KVL walk" between them and sum the potential changes.
 

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  • #13
so for V13=V12+V32
 
  • #14
DODGEVIPER13 said:
so for V13=V12+V32

By convention V13 would be the potential at 1 with respect to 3. So start at 3 and "walk" to 1. Pay attention to the polarities of the sources along the way.
 
  • #15
Ahhh woops V13=V12-V32
 
  • #16
V34=sqrt((V14)^2+(V32)^2+(V12)^2) right?
 
  • #17
or should it be V34=sqrt(-(V14)^2+(V32)^2+(V12)^2)
 
  • #18
hmmmmmmm V31=V32-V12 so that V34=V31-V41
 
  • #19
DODGEVIPER13 said:
V34=sqrt((V14)^2+(V32)^2+(V12)^2) right?

What are you trying to accomplish? The individual voltages are in complex form and you can sum them by summing their real and imaginary components separately.

If you want the magnitude of the result, then do the square root of the sum of the squares of its components.
 
  • #20
so I solved V13=9.801+j2.271
 
  • #21
I was trying to use Pythagorean Theorem which I know is incorrect sorry
 
  • #22
did you read my new post after that is that close to how to solve for V34
 
  • #23
more specifically post #18
 
  • #24
DODGEVIPER13 said:
did you read my new post after that is that close to how to solve for V34

DODGEVIPER13 said:
more specifically post #18

I think you're still tripping over the directions of the potential changes. If you calculate a new potential difference, like V31, add a new branch to the diagram with the appropriate label and source direction. You can just use arrows to indicate polarity if the diagram starts getting too cluttered.

attachment.php?attachmentid=61991&stc=1&d=1379645184.gif


So for V34 you would start at V4 and walk through +V14 and +V31, right?
 

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  • #25
ok well V31=V32-V12=-9.801-j2.271
 
  • #26
then V34=V14+V31
 
  • #27
-7.831-j1.923=V34 hopefully?
 
  • #28
DODGEVIPER13 said:
-7.831-j1.923=V34 hopefully?

That looks okay.
 
  • #29
V24=-V12+v14 = -5.824-j4.152
 

1. What is a phasor in relation to circuit analysis?

A phasor is a graphical representation of a sinusoidal wave that is used in circuit analysis to simplify complex calculations. It is represented by a vector with a magnitude and angle, and it represents the amplitude and phase of the waveform at a specific time.

2. How do you convert phasors to complex units in a circuit?

To convert a phasor to complex units, you can use the formula V = V0e^(jθ), where V is the complex representation of the phasor, V0 is the magnitude of the phasor, and θ is the angle of the phasor. This formula allows you to convert the magnitude and angle of the phasor into a complex number, which can then be used in circuit calculations.

3. What are the common phasors used in circuit analysis?

The most commonly used phasors in circuit analysis are V21, V13, V34, and V24. These represent the voltage between nodes 2 and 1, 1 and 3, 3 and 4, and 2 and 4, respectively. They are often used in combination with other phasors to analyze more complex circuits.

4. How do you calculate V21, V13, V34, and V24 in a circuit?

To calculate V21, V13, V34, and V24, you can use the Kirchhoff's Laws and Ohm's Law. First, use Kirchhoff's Voltage Law to determine the voltages around a closed loop in the circuit. Then, use Ohm's Law to calculate the voltage drops across resistors. Finally, use the complex representation of the voltage drops to calculate the phasors V21, V13, V34, and V24.

5. What is the significance of calculating phasors in a circuit?

Calculating phasors in a circuit allows for a simplified analysis of complex AC circuits. It helps in understanding the behavior of the circuit at different frequencies and can aid in determining the voltage and current at different points in the circuit. Phasor calculations can also be used to design and optimize circuits for specific applications.

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