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I have an intra-day chart and I am trying to figure out how to calculate support and resistance levels, anyone knows an algorithm for doing that, or a good starting point?

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You may also want to check this question: – ticktock Feb 26 at 14:28

3 Answers 3

up vote 12 down vote accepted

Yes, a very simple algorithm is to choose a timeframe, say 100 bars, then look for local turning points, or Maxima and Minima. Maxima and Minima can be computed from a smoothed closing price by using the 1st and second derivative (dy/dx and d^2y/dx). Where dy/dx = zero and d^y/dx is positive, you have a minima, when dy/dx = zero and d^2y/dx is negative, you have a maxima.

In practical terms this could be computed by iterating over your smoothed closing price series and looking at three adjacent points. If the points are lower/higher/lower in relative terms then you have a maxima, else higher/lower/higher you have a minima. You may wish to fine-tune this detection method to look at more points (say 5, 7) and only trigger if the edge points are a certain % away from the centre point. this is similar to the algorithm that the ZigZag indicator uses.

Once you have local maxima and minima, you then want to look for clusters of turning points within a certain distance of each other in the Y-Direction. this is simple. Take the list of N turning points and compute the Y-distance between it and each of the other discovered turning points. If the distance is less than a fixed constant then you have found two "close" turning points, indicating possible support/resistance.

You could then rank your S/R lines, so two turning points at $20 is less important than three turning points at $20 for instance.

An extension to this would be to compute trendlines. With the list of turning points discovered now take each point in turn and select two other points, trying to fit a straight line equation. If the equation is solvable within a certain error margin, you have a sloping trendline. If not, discard and move on to the next triplet of points.

The reason why you need three at a time to compute trendlines is any two points can be used in the straight line equation. Another way to compute trendlines would be to compute the straight line equation of all pairs of turning points, then see if a third point (or more than one) lies on the same straight line within a margin of error. If 1 or more other points does lie on this line, bingo you have calculated a Support/Resistance trendline.

I hope this helps. No code examples sorry, I'm just giving you some ideas on how it could be done. In summary:

Inputs to the system

  • Lookback period L (number of bars)
  • Closing prices for L bars
  • Smoothing factor (to smooth closing price)
  • Error Margin or Delta (minimum distance between turning points to constitute a match)


  • List of turning points, call them tPoints[] (x,y)
  • List of potential trendlines, each with the line equation (y = mx + c)

Best regards,

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Thank you Andrew for your detailed answer, I am going to check that – Yaron Dec 22 '11 at 18:30
Hi Andrew, I checked your idea, I still cannot figure out how to calculate the minima and maxima, because I don't have the formula of y (x=time value, y = price), and I need it in order to get 1st and 2nd derivatives, can you explain? thank you very much. Yaron – Yaron Dec 25 '11 at 12:01
What you need to do is perform numerical differentiation of the smoothed closing prices to determine dy/dx: . After that perform differentiation again to find d^2y/dx. Note that there are other simpler ways to find the turning points, check out zigzag indicator: – Dr. ABT Dec 25 '11 at 16:37
Hi Andrew, thank you for your answer. I think I can use EMA20 as the smoothed price list. I know how to differentiate a function, but not a list of values, do you have a tip on how to do this? thank you for everything, you helped me a lot already – Yaron Dec 29 '11 at 12:33
Yes, its surprisingly simple actually. Please see this previous answer here:… To differentiate a function you can compute [f(x+h) - f(x-h)] / 2h (where h=1 and f(x) is your input array). In practice this means if your array is length 10 (indices 0..9) then you compute diff[8] = (input[9] - input[7]) / 2. – Dr. ABT Dec 29 '11 at 16:39

I am using a much less complex algorithm in my algorithmic trading system.

Following steps are one side of the algorithm and are used for calculating support levels. Please read notes below the algorithm to understand how to calculate resistance levels.


  1. Break timeseries into segments of size N (Say, N = 5)
  2. Identify minimum values of each segment, you will have an array of minimum values from all segments = :arrayOfMin
  3. Find minimum of (:arrayOfMin) = :minValue
  4. See if any of the remaining values fall within range (X% of :minValue) (Say, X = 1.3%)
  5. Make a separate array (:supportArr)
    • add values within range & remove these values from :arrayOfMin
    • also add :minValue from step 3
  6. Calculating support (or resistance)

    • Take a mean of this array = support_level
    • If support is tested many times, then it is considered strong.
    • strength_of_support = supportArr.length
    • level_type (SUPPORT|RESISTANCE) = Now, if current price is below support then support changes role and becomes resistance
  7. Repeat steps 3 to 7 until :arrayOfMin is empty

  8. You will have all support/resistance values with a strength. Now smoothen these values, if any support levels are too close then eliminate one of them.
  9. These support/resistance were calculated considering support levels search. You need perform steps 2 to 9 considering resistance levels search. Please see notes and implementation.


  • Adjust the values of N & X to get more accurate results.
    • Example, for less volatile stocks or equity indexes use (N = 10, X = 1.2%)
    • For high volatile stocks use (N = 22, X = 1.5%)
  • For resistance, the procedure is exactly opposite (use maximum function instead of minimum)
  • This algorithm was purposely kept simple to avoid complexity, it can be improved to give better results.

Here's my implementation:

public interface ISupportResistanceCalculator {

 * Identifies support / resistance levels.
 * @param timeseries
 *            timeseries
 * @param beginIndex
 *            starting point (inclusive)
 * @param endIndex
 *            ending point (exclusive)
 * @param segmentSize
 *            number of elements per internal segment
 * @param rangePct
 *            range % (Example: 1.5%)
 * @return A tuple with the list of support levels and a list of resistance
 *         levels
Tuple<List<Level>, List<Level>> identify(List<Float> timeseries,
        int beginIndex, int endIndex, int segmentSize, float rangePct);

Main calculator class

package com.perseus.analysis.calculator.technical.trend;

import static com.perseus.analysis.constant.LevelType.RESISTANCE;
import static com.perseus.analysis.constant.LevelType.SUPPORT;

import java.util.ArrayList;
import java.util.Collections;
import java.util.Date;
import java.util.LinkedList;
import java.util.List;
import java.util.Set;
import java.util.TreeSet;

import com.perseus.analysis.calculator.mean.IMeanCalculator;
import com.perseus.analysis.calculator.timeseries.ITimeSeriesCalculator;
import com.perseus.analysis.constant.LevelType;
import com.perseus.analysis.model.Tuple;
import com.perseus.analysis.model.technical.Level;
import com.perseus.analysis.model.timeseries.ITimeseries;
import com.perseus.analysis.util.CollectionUtils;

 * A support and resistance calculator.
 * @author PRITESH
public class SupportResistanceCalculator implements
        ISupportResistanceCalculator {

    static interface LevelHelper {

        Float aggregate(List<Float> data);

        LevelType type(float level, float priceAsOfDate, final float rangePct);

        boolean withinRange(Float node, float rangePct, Float val);


    static class Support implements LevelHelper {

        public Float aggregate(final List<Float> data) {
            return Collections.min(data);

        public LevelType type(final float level, final float priceAsOfDate,
                final float rangePct) {
            final float threshold = level * (1 - (rangePct / 100));
            return (priceAsOfDate < threshold) ? RESISTANCE : SUPPORT;

        public boolean withinRange(final Float node, final float rangePct,
                final Float val) {
            final float threshold = node * (1 + (rangePct / 100f));
            if (val < threshold)
                return true;
            return false;


    static class Resistance implements LevelHelper {

        public Float aggregate(final List<Float> data) {
            return Collections.max(data);

        public LevelType type(final float level, final float priceAsOfDate,
                final float rangePct) {
            final float threshold = level * (1 + (rangePct / 100));
            return (priceAsOfDate > threshold) ? SUPPORT : RESISTANCE;

        public boolean withinRange(final Float node, final float rangePct,
                final Float val) {
            final float threshold = node * (1 - (rangePct / 100f));
            if (val > threshold)
                return true;
            return false;


    private static final int SMOOTHEN_COUNT = 2;

    private static final LevelHelper SUPPORT_HELPER = new Support();

    private static final LevelHelper RESISTANCE_HELPER = new Resistance();

    private final ITimeSeriesCalculator tsCalc;

    private final IMeanCalculator meanCalc;

    public SupportResistanceCalculator(final ITimeSeriesCalculator tsCalc,
            final IMeanCalculator meanCalc) {
        this.tsCalc = tsCalc;
        this.meanCalc = meanCalc;

    public Tuple<List<Level>, List<Level>> identify(
            final List<Float> timeseries, final int beginIndex,
            final int endIndex, final int segmentSize, final float rangePct) {

        final List<Float> series = this.seriesToWorkWith(timeseries,
                beginIndex, endIndex);
        // Split the timeseries into chunks
        final List<List<Float>> segments = this.splitList(series, segmentSize);
        final Float priceAsOfDate = series.get(series.size() - 1);

        final List<Level> levels = Lists.newArrayList();
        this.identifyLevel(levels, segments, rangePct, priceAsOfDate,

        this.identifyLevel(levels, segments, rangePct, priceAsOfDate,

        final List<Level> support = Lists.newArrayList();
        final List<Level> resistance = Lists.newArrayList();
        this.separateLevels(support, resistance, levels);

        // Smoothen the levels
        this.smoothen(support, resistance, rangePct);

        return new Tuple<>(support, resistance);

    private void identifyLevel(final List<Level> levels,
            final List<List<Float>> segments, final float rangePct,
            final float priceAsOfDate, final LevelHelper helper) {

        final List<Float> aggregateVals = Lists.newArrayList();

        // Find min/max of each segment
        for (final List<Float> segment : segments) {

        while (!aggregateVals.isEmpty()) {
            final List<Float> withinRange = new ArrayList<>();
            final Set<Integer> withinRangeIdx = new TreeSet<>();

            // Support/resistance level node
            final Float node = helper.aggregate(aggregateVals);

            // Find elements within range
            for (int i = 0; i < aggregateVals.size(); ++i) {
                final Float f = aggregateVals.get(i);
                if (helper.withinRange(node, rangePct, f)) {

            // Remove elements within range
            CollectionUtils.remove(aggregateVals, withinRangeIdx);

            // Take an average
            final float level = this.meanCalc.mean(
                    withinRange.toArray(new Float[] {}), 0, withinRange.size());
            final float strength = withinRange.size();

            levels.add(new Level(helper.type(level, priceAsOfDate, rangePct),
                    level, strength));



    private List<List<Float>> splitList(final List<Float> series,
            final int segmentSize) {
        final List<List<Float>> splitList = CollectionUtils

        if (splitList.size() > 1) {
            // If last segment it too small
            final int lastIdx = splitList.size() - 1;
            final List<Float> last = splitList.get(lastIdx);
            if (last.size() <= (segmentSize / 1.5f)) {
                // Remove last segment
                // Move all elements from removed last segment to new last
                // segment
                splitList.get(lastIdx - 1).addAll(last);

        return splitList;

    private void separateLevels(final List<Level> support,
            final List<Level> resistance, final List<Level> levels) {
        for (final Level level : levels) {
            if (level.getType() == SUPPORT) {
            } else {

    private void smoothen(final List<Level> support,
            final List<Level> resistance, final float rangePct) {
        for (int i = 0; i < SMOOTHEN_COUNT; ++i) {
            this.smoothen(support, rangePct);
            this.smoothen(resistance, rangePct);

     * Removes one of the adjacent levels which are close to each other.
    private void smoothen(final List<Level> levels, final float rangePct) {
        if (levels.size() < 2)

        final List<Integer> removeIdx = Lists.newArrayList();

        for (int i = 0; i < (levels.size() - 1); i++) {
            final Level currentLevel = levels.get(i);
            final Level nextLevel = levels.get(i + 1);
            final Float current = currentLevel.getLevel();
            final Float next = nextLevel.getLevel();
            final float difference = Math.abs(next - current);
            final float threshold = (current * rangePct) / 100;

            if (difference < threshold) {
                final int remove = currentLevel.getStrength() >= nextLevel
                        .getStrength() ? i : i + 1;
                i++; // start with next pair

        CollectionUtils.remove(levels, removeIdx);

    private List<Float> seriesToWorkWith(final List<Float> timeseries,
            final int beginIndex, final int endIndex) {

        if ((beginIndex == 0) && (endIndex == timeseries.size()))
            return timeseries;

        return timeseries.subList(beginIndex, endIndex);



Here are some supporting classes:

public enum LevelType {



public class Tuple<A, B> {

    private final A a;

    private final B b;

    public Tuple(final A a, final B b) {
        this.a = a;
        this.b = b;

    public final A getA() {
        return this.a;

    public final B getB() {
        return this.b;

    public String toString() {
        return "Tuple [a=" + this.a + ", b=" + this.b + "]";


public abstract class CollectionUtils {

 * Removes items from the list based on their indexes.
 * @param list
 *            list
 * @param indexes
 *            indexes this collection must be sorted in ascending order
public static <T> void remove(final List<T> list,
        final Collection<Integer> indexes) {
    int i = 0;
    for (final int idx : indexes) {
        list.remove(idx - i++);

 * Splits the given list in segments of the specified size.
 * @param list
 *            list
 * @param segmentSize
 *            segment size
 * @return segments
public static <T> List<List<T>> splitList(final List<T> list,
        final int segmentSize) {
    int from = 0, to = 0;
    final List<List<T>> result = new ArrayList<>();

    while (from < list.size()) {
        to = from + segmentSize;
        if (to > list.size()) {
            to = list.size();
        result.add(list.subList(from, to));
        from = to;

    return result;


 * This class represents a support / resistance level.
 * @author PRITESH
public class Level implements Serializable {

    private static final long serialVersionUID = -7561265699198045328L;

    private final LevelType type;

    private final float level, strength;

    public Level(final LevelType type, final float level) {
        this(type, level, 0f);

    public Level(final LevelType type, final float level, final float strength) {
        this.type = type;
        this.level = level;
        this.strength = strength;

    public final LevelType getType() {
        return this.type;

    public final float getLevel() {
        return this.level;

    public final float getStrength() {
        return this.strength;

    public String toString() {
        return "Level [type=" + this.type + ", level=" + this.level
                + ", strength=" + this.strength + "]";

share|improve this answer
does it work well? – experquisite Nov 11 at 23:05
Yes it does work for sure. But its not perfect, once you understand the algorithm then you have to tweak it to get more and more accurate results. It gives you that flexibility. First try to understand the steps, then I would recommend to try it with stock data. Please check the "Notes" section of the answer. – Pritesh Mhatre Nov 16 at 7:38

I put together a package that implements support and resistance trendlines like what you're asking about. Here are a few examples of some examples:

import numpy as np
import as pd
from matplotlib.pyplot import *
gentrends('fb', window = 1.0/3.0)


That example just pulls the adjusted close prices, but if you have intraday data already loaded in you can also feed it raw data as a numpy array and it will implement the same algorithm on that data as it would if you just fed it a ticker symbol.

Not sure if this is exactly what you were looking for but hopefully this helps get you started. The code and some more explanation can be found on the GitHub page where I have it hosted:

share|improve this answer
Thanks! I'll give it a try – Yaron Apr 14 '14 at 10:39
Does it simply find the two largest and smallest values and calculate the lines passsing from those points ? – nurettin Aug 1 '14 at 18:36
For this specific function, it finds the global max and min of the data, and then finds the 2nd largest max and min outside of the window period you feed it. So if you give it a window of 30 periods, it will find the highest max/min that is at least 30 periods away from the global max/min. It looks forward first, but if there aren't 30 periods left in the series, then it will look backwards. Here I feed it a window of 1.0/3.0, which it interprets as one-third of the length of the data. There are other methods in there that provide some more flexible approaches if you're interested :) – jamos125 Aug 1 '14 at 18:56

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