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I’m no expert programmer, but I’m attempting to change the way in which some technical indicators are displayed in a financial charting package called TradeStation (not that the specific charting supplier is relevant).

Here is the problem: Most indicators are plotted around a Zero point, sometimes they oscillate close to this point and sometimes far away. I would like to change the way in which the indicators are plotted so that they oscillate around Zero much more. But here is the tricky part, I don’t wish to distort their shape too much; some change is fine and inevitable, but I still would like the indicators to be recognisable for what they originally were.

In the past I have tried many ways, one way was using a logarithmic type scale, but this was not successful as it made any oscillation that was at a very high value almost inconsequential- which is not the goal. The goal is to try to keep any one oscillation of the indicator almost the same, but change the placement of it so that its closer to Zero (centre). Or put another way; the goal is to make the indicators perform similar shaped oscillations, but the centre of these oscillations should be closer to Zero (the centre of the indicators scale).

Does anyone know of, or can think of a way that this can be done? Are there any algorithms that might help keep any price series oscillating more around a centre point without too much distortion to the original?

Any help on this would be greatly appreciated, thank you.

==UPDATE== enter image description here The pink line is the original oscillator, the black line I have drawn in. It crudely represents what my goal would be for this. The circled areas show where the drawn in line crosses Zero so that its Zero value is roughly in the center of the oscillation... But the overall shape of the oscillation remains recognizable compared to the original one, also there is less discrepancy in the highs and lows of each oscillation; i.e. they are more similar in value . I have tried adding several different Detrend functions to various indicators but I have found that this distorts the shape for too much.


I have tried dividing reducing linearly the y axis by 50% and 80%, Unfortunately this seems to just act in the same was as a scale factor would? Is this correct? It does not seem to change the relationship between different oscillations. If you see my example plot, the drawn in black line has more stable high and low oscillations i.e they are more similar in value/size and this is the key goal.

Next, I am going to try to add a high pass filter to the plot to see what result that gives and if it is closer in any way to my goal.

As usual, feel free to post any comments as they are gratefully received.



Hi Guys, I have also implemented a high pass filter to an indicator. This did not do the trick either. This also seems to act as a scale factor. What I am after essentially, is to make large oscillations smaller, and small oscillations larger. Bringing any indicator used into a more synchronised range- and do this while maintaining the basic properties of the indicator in question... A better way to describe it may be that I'm after a damping formula?

Does anyone have any other ideas, or things I should be trying? Cheers!!!

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A picture is worth a thousand words - Can you post a sample chart, and a sample of 'modified' chart that would represent what you want ? –  Agnius Vasiliauskas Mar 28 '11 at 8:18
@Christopher Allow me to welcome you to StackOverflow and remind three things we usually do here: 1) As you receive help, try to give it too answering questions in your area of expertise 2) Read the FAQs 3) When you see good Q&A, vote them upusing the gray triangles, as the credibility of the system is based on the reputation that users gain by sharing their knowledge. Also remember to accept the answer that better solves your problem, if any, by pressing the checkmark sign –  belisarius Mar 29 '11 at 0:28
@Christopher: Use the same email to login. So you will be able to edit your questions, etc. Now you created 2 accounts: this and this –  abatishchev Mar 30 '11 at 12:50
Welcome to Stack Overflow! I've merged your two accounts together. Please read this Faq entry about cookie-based accounts. Also, StackOverflow isn't a forum; if you have a new question, please ask a new question. If you want to include more information in your question, please edit it. If you want to interact with one of the people who has answered, you can leave them a comment. –  Will Mar 30 '11 at 13:16
Answering your update 3, your hi-pass filter will do. Instead of deleting the low frequency components, just multiply each component using an exponential decay with the frquency –  belisarius Apr 4 '11 at 12:14
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3 Answers

If you want to do something tailor-made, you could for example filter the low frequency components of the Fourier transform.

Suppose we have the following signal:

enter image description here

Then we calculate the FFT, and keep only the higher frequency components. Let's say we disregard the first 1.5% of the components. The resulting Plot of the original signal and the resulting oscillating one is:

enter image description here


Edit 2

This is what you can expect from a hi-pass filter as described above, adding an exponential damping, instead of just disposing the low frequency components.

Program in Mathematica (just in case):

centerOsc[x_] := 
  Module[{list, n, fp, coef, s}, 
   list = (Transpose@FinancialData[#, "Jan. 1, 2005"])[[2]] &@x;
   n = Length@list;
   fp = Transpose[{N[Range[n]]/n, list}];
   coef = FourierDST[list, 1]/Sqrt[n/2];
   coef = Table[N[coef[[i]] (1 - E^(-i/6))], {i, 1, Length@coef}];
   s = IntegerPart[Length@coef/100]; s = 1;
   {fp, {#, 
       Sum[coef[[r]]*Sin[Pi r #], {r, s, n - 1}]} & /@ (N[Range[n]]/
l = {"GE", "GOOG", "IBM", "MSFT"} ;(*Real prices from*)
     Axes -> False, Frame -> True, PlotLabel -> #,
     PlotRange -> {{0.1, .9}, Full}, 
     Epilog -> Line[{{0, 0}, {1, 0}}]] & /@ l, 2]

enter image description here

Edit 2

Based on your last update, it seems that what you want can be achieved easier. Just see what you get by dividing reducing linearly the y axis by 50% and 80% (using your data, extracted from your plot):

enter image description here

and compare with your plot:

enter image description here

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The first thing I suggest you do is too standardize all of the indicators to a mean of 0 and standard deviation of 1. This at least will center all of your indicators around 0.


-Ralph Winters

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Thanks very much so far people. I really appreciate you all spending the time to answer. I have lots to be getting on with as I will probably experiment with a few different ways outlined here. I'm sure I will have more questions, and I will keep you all updated!!! –  Christopher Mar 29 '11 at 0:15
Update 2 is now added... –  Christopher Mar 30 '11 at 14:25
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I've marked low frequency component of input/output signals in your example: enter image description here Seems really as @belisarius says what you want is - just do FFT on signal and remove low frequency parts. That is - you need high pass filter algorithm. BTW, high pass filter can be also implemented with 1D convolution and high-pass kernel. For example,- for 3 component kernel vector, high-pass kernel could be [-1; 3; -1]. In my opinion high-pass filter implementation with convolution is easiest one. But usually implementation through FFT is fastest one in relation to cpu usage.


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