Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

While working on Exercise 6.5 of Ch06 in Dr. Middlebrook's D-OA method, I tried to make bode plot of the transfer function:

bodeplot[s/100+100/s*(1+10/s)] (input to wolframalpha)

in J

results from wolframalpha

Somehow the J code phase plot doesn't agree with Mathematica's result, though the magnitude plot matches fine.

Anything wrong with my J code?

Af =: 4 : 0"_ 0
s=.0j1*y
'w q'=.x
f=.(s%w) + (w%s)*(1+w%q*s)
20*10^. | f
)

Pf =: 4 : 0"_ 0
s=.0j1*y
'w q'=.x
f=.(s%w) + (w%s)*(1+w%q*s)
(180%o.1)* 1{ *. f
)

load 'plot'

plot (; (100 10 Af (10 ^ ]))) 0.02*i.200

plot (; (100 10 Pf (10 ^ ]))) 0.02*i.200

enter image description here

To be more general, say a complex variable on the unit circle in the complex plane z = cos x + I sin x

If we plot its phase angle, there will be a jump at 180 degree (from 180 to -180)

z_unit_circle =. ((2 o. ]) + (0j1 * (1 o.]))) @ (180 %~ o.)

plot (180%o.1)*1{"1 *. z_unit_circle i.360

unit circle phase angle

I think that's what happens when phase angle goes around 180 or -180 in the earlier J bode plot.

To avoid this jump, we can make use of the relationship Tan(Im(z)/Re(z)) = Tan(-180 + Im(z)/Re(z)), i.e. to turn -180 before hand.

phase_angle =. _180 + (180 % o.1) * (_3 o. %~/) @ +.

Pf =: 4 : 0"_ 0
s=.0j1*y
'w q'=.x
f=.(s%w) + (w%s)*(1+w%q*s)
phase_angle f
)

plot (; (100 10 Pf (10 ^ ]))) 0.02*i.200

This is essentially the same as the answer provided by Eelvex.

However this phase_angle[z] has more jumps than Arg[z]

plot phase_angle"1 z_unit_circle i.360

third quadrant

So my question is how to make the correct bode plot in J. In other words, knowing the phase angle goes from 3rd quadrant into 2nd quadrant, thus -180 before hand

share|improve this question

1 Answer 1

Don't use Arg (*.), use -180 + arctan(Im(T)/Re(T))

 plot  180-~(180%o.1) *  _3 o. %~/"1  +. T 0j1 * (10 ^  3-~0.1*i.80)

enter image description here

(where T is your transfer function: T =: 3 : '(y%100) + (100*(1+10%y))%y')

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.