# My problem

I tried many libraries on Github but all of them did not produce matching results for TradingView so I followed the formula on this link to calculate RSI indicator. I calculated it with Excel and collated the results with TradingView. I know it's absolutely correct but, but I didn't find a way to calculate it with Pandas.

# Formula

``````              100
RSI = 100 - --------
1 + RS

RS = Average Gain / Average Loss

The very first calculations for average gain and average loss are simple
14-period averages:

First Average Gain = Sum of Gains over the past 14 periods / 14.
First Average Loss = Sum of Losses over the past 14 periods / 14

The second, and subsequent, calculations are based on the prior averages
and the current gain loss:

Average Gain = [(previous Average Gain) x 13 + current Gain] / 14.
Average Loss = [(previous Average Loss) x 13 + current Loss] / 14.
``````

## Expected Results

``````     close   change     gain     loss     avg_gian    avg_loss        rs  \
0    4724.89      NaN      NaN      NaN          NaN         NaN       NaN
1    4378.51  -346.38     0.00   346.38          NaN         NaN       NaN
2    6463.00  2084.49  2084.49     0.00          NaN         NaN       NaN
3    9838.96  3375.96  3375.96     0.00          NaN         NaN       NaN
4   13716.36  3877.40  3877.40     0.00          NaN         NaN       NaN
5   10285.10 -3431.26     0.00  3431.26          NaN         NaN       NaN
6   10326.76    41.66    41.66     0.00          NaN         NaN       NaN
7    6923.91 -3402.85     0.00  3402.85          NaN         NaN       NaN
8    9246.01  2322.10  2322.10     0.00          NaN         NaN       NaN
9    7485.01 -1761.00     0.00  1761.00          NaN         NaN       NaN
10   6390.07 -1094.94     0.00  1094.94          NaN         NaN       NaN
11   7730.93  1340.86  1340.86     0.00          NaN         NaN       NaN
12   7011.21  -719.72     0.00   719.72          NaN         NaN       NaN
13   6626.57  -384.64     0.00   384.64          NaN         NaN       NaN
14   6371.93  -254.64     0.00   254.64   931.605000  813.959286  1.144535
15   4041.32 -2330.61     0.00  2330.61   865.061786  922.291480  0.937948
16   3702.90  -338.42     0.00   338.42   803.271658  880.586374  0.912201
17   3434.10  -268.80     0.00   268.80   745.895111  836.887347  0.891273
18   3813.69   379.59   379.59     0.00   719.730460  777.109680  0.926163
19   4103.95   290.26   290.26     0.00   689.053999  721.601845  0.954895
20   5320.81  1216.86  1216.86     0.00   726.754428  670.058856  1.084613
21   8555.00  3234.19  3234.19     0.00   905.856968  622.197509  1.455899
22  10854.10  2299.10  2299.10     0.00  1005.374328  577.754830  1.740140

rsi_14
0         NaN
1         NaN
2         NaN
3         NaN
4         NaN
5         NaN
6         NaN
7         NaN
8         NaN
9         NaN
10        NaN
11        NaN
12        NaN
13        NaN
14  53.369848
15  48.399038
16  47.704239
17  47.125561
18  48.083322
19  48.846358
20  52.029461
21  59.281719
22  63.505515
``````

# My Code

## Import

``````import pandas as pd
import numpy as np
``````

``````df = pd.read_csv("rsi_14_test_data.csv")
close = df['close']
print(close)

0      4724.89
1      4378.51
2      6463.00
3      9838.96
4     13716.36
5     10285.10
6     10326.76
7      6923.91
8      9246.01
9      7485.01
10     6390.07
11     7730.93
12     7011.21
13     6626.57
14     6371.93
15     4041.32
16     3702.90
17     3434.10
18     3813.69
19     4103.95
20     5320.81
21     8555.00
22    10854.10
Name: close, dtype: float64
``````

## Change

Calculate change every row

``````change = close.diff(1)
print(change)

0         NaN
1     -346.38
2     2084.49
3     3375.96
4     3877.40
5    -3431.26
6       41.66
7    -3402.85
8     2322.10
9    -1761.00
10   -1094.94
11    1340.86
12    -719.72
13    -384.64
14    -254.64
15   -2330.61
16    -338.42
17    -268.80
18     379.59
19     290.26
20    1216.86
21    3234.19
22    2299.10
Name: close, dtype: float64
``````

## Gain and loss

get gain and loss from change

``````is_gain, is_loss = change > 0, change < 0
gain, loss = change, -change
gain[is_loss] = 0
loss[is_gain] = 0
​
gain.name = 'gain'
loss.name = 'loss'
print(loss)

0         NaN
1      346.38
2        0.00
3        0.00
4        0.00
5     3431.26
6        0.00
7     3402.85
8        0.00
9     1761.00
10    1094.94
11       0.00
12     719.72
13     384.64
14     254.64
15    2330.61
16     338.42
17     268.80
18       0.00
19       0.00
20       0.00
21       0.00
22       0.00
Name: loss, dtype: float64
``````

## Calculate fist avg gain and loss

Mean of n prior rows

``````n = 14
avg_gain = change * np.nan
avg_loss = change * np.nan
​
avg_gain[n] = gain[:n+1].mean()
avg_loss[n] = loss[:n+1].mean()
​
avg_gain.name = 'avg_gain'
avg_loss.name = 'avg_loss'
​
avg_df = pd.concat([gain, loss, avg_gain, avg_loss], axis=1)
print(avg_df)

gain     loss  avg_gain    avg_loss
0       NaN      NaN       NaN         NaN
1      0.00   346.38       NaN         NaN
2   2084.49     0.00       NaN         NaN
3   3375.96     0.00       NaN         NaN
4   3877.40     0.00       NaN         NaN
5      0.00  3431.26       NaN         NaN
6     41.66     0.00       NaN         NaN
7      0.00  3402.85       NaN         NaN
8   2322.10     0.00       NaN         NaN
9      0.00  1761.00       NaN         NaN
10     0.00  1094.94       NaN         NaN
11  1340.86     0.00       NaN         NaN
12     0.00   719.72       NaN         NaN
13     0.00   384.64       NaN         NaN
14     0.00   254.64   931.605  813.959286
15     0.00  2330.61       NaN         NaN
16     0.00   338.42       NaN         NaN
17     0.00   268.80       NaN         NaN
18   379.59     0.00       NaN         NaN
19   290.26     0.00       NaN         NaN
20  1216.86     0.00       NaN         NaN
21  3234.19     0.00       NaN         NaN
22  2299.10     0.00       NaN         NaN
``````

The very first calculations for average gain and the average loss is ok but I don't know how to apply pandas.core.window.Rolling.apply for the second, and subsequent because they are in many rows and different columns. It may be something like this:

``````avg_gain[n] = (avg_gain[n-1]*13 + gain[n]) / 14
``````

## My Wish - My Question

• The best way to calculate and work with technical indicators?
• Complete the above code in "Pandas Style".
• Does the traditional way of coding with loops reduce performance compared to Pandas?
• Welcome to Stackoverflow. Well done for this nicely written question! Jul 12 '19 at 11:59
• You are probably better off just using (or copying/pasting) the implementation from github.com/peerchemist/finta than reinventing the wheel Jul 13 '19 at 10:55
• @GustavoBezerra I don’t know why all libraries I found in Github have the same function for RSI but they didn’t produce the correct results like I did with Excel and TradingView Jul 13 '19 at 11:13

The average gain and loss are calculated by a recursive formula, which can't be vectorized with numpy. We can, however, try and find an analytical (i.e. non-recursive) solution for calculating the individual elements. Such a solution can then be implemented using numpy.

Denoting the average gain as `y` and the current gain as `x`, we get `y[i] = a*y[i-1] + b*x[i]`, where `a = 13/14` and `b = 1/14` for `n = 14`. Unwrapping the recursion leads to: (sorry for the picture, was just to cumbersome to type it)

This can be efficiently calculated in numpy using `cumsum` (rma = running moving average):

``````import pandas as pd
import numpy as np

df = pd.DataFrame({'close':[4724.89, 4378.51,6463.00,9838.96,13716.36,10285.10,
10326.76,6923.91,9246.01,7485.01,6390.07,7730.93,
7011.21,6626.57,6371.93,4041.32,3702.90,3434.10,
3813.69,4103.95,5320.81,8555.00,10854.10]})
n = 14

def rma(x, n, y0):
a = (n-1) / n
ak = a**np.arange(len(x)-1, -1, -1)
return np.r_[np.full(n, np.nan), y0, np.cumsum(ak * x) / ak / n + y0 * a**np.arange(1, len(x)+1)]

df['change'] = df['close'].diff()
df['gain'] = df.change.mask(df.change < 0, 0.0)
df['loss'] = -df.change.mask(df.change > 0, -0.0)
df['avg_gain'] = rma(df.gain[n+1:].to_numpy(), n, np.nansum(df.gain.to_numpy()[:n+1])/n)
df['avg_loss'] = rma(df.loss[n+1:].to_numpy(), n, np.nansum(df.loss.to_numpy()[:n+1])/n)
df['rs'] = df.avg_gain / df.avg_loss
df['rsi_14'] = 100 - (100 / (1 + df.rs))
``````

Output of `df.round(2)`:

``````         close   change     gain     loss  avg_gain  avg_loss    rs    rsi  rsi_14
0      4724.89      NaN      NaN      NaN       NaN       NaN   NaN    NaN     NaN
1      4378.51  -346.38     0.00   346.38       NaN       NaN   NaN    NaN     NaN
2      6463.00  2084.49  2084.49     0.00       NaN       NaN   NaN    NaN     NaN
3      9838.96  3375.96  3375.96     0.00       NaN       NaN   NaN    NaN     NaN
4     13716.36  3877.40  3877.40     0.00       NaN       NaN   NaN    NaN     NaN
5     10285.10 -3431.26     0.00  3431.26       NaN       NaN   NaN    NaN     NaN
6     10326.76    41.66    41.66     0.00       NaN       NaN   NaN    NaN     NaN
7      6923.91 -3402.85     0.00  3402.85       NaN       NaN   NaN    NaN     NaN
8      9246.01  2322.10  2322.10     0.00       NaN       NaN   NaN    NaN     NaN
9      7485.01 -1761.00     0.00  1761.00       NaN       NaN   NaN    NaN     NaN
10     6390.07 -1094.94     0.00  1094.94       NaN       NaN   NaN    NaN     NaN
11     7730.93  1340.86  1340.86     0.00       NaN       NaN   NaN    NaN     NaN
12     7011.21  -719.72     0.00   719.72       NaN       NaN   NaN    NaN     NaN
13     6626.57  -384.64     0.00   384.64       NaN       NaN   NaN    NaN     NaN
14     6371.93  -254.64     0.00   254.64    931.61    813.96  1.14  53.37   53.37
15     4041.32 -2330.61     0.00  2330.61    865.06    922.29  0.94  48.40   48.40
16     3702.90  -338.42     0.00   338.42    803.27    880.59  0.91  47.70   47.70
17     3434.10  -268.80     0.00   268.80    745.90    836.89  0.89  47.13   47.13
18     3813.69   379.59   379.59     0.00    719.73    777.11  0.93  48.08   48.08
19     4103.95   290.26   290.26     0.00    689.05    721.60  0.95  48.85   48.85
20     5320.81  1216.86  1216.86     0.00    726.75    670.06  1.08  52.03   52.03
21     8555.00  3234.19  3234.19     0.00    905.86    622.20  1.46  59.28   59.28
22    10854.10  2299.10  2299.10     0.00   1005.37    577.75  1.74  63.51   63.51
``````

Concerning your last question about performance: explicite loops in python / pandas are terrible, avoid them whenever you can. If you can't, try cython or numba.

To illustrate this, I made a small comparison of my numpy solution with dimitris_ps' loop solution:

``````import pandas as pd
import numpy as np
import timeit

mult = 1        # length of dataframe = 23 * mult
number = 1000   # number of loop for timeit

df0 = pd.DataFrame({'close':[4724.89, 4378.51,6463.00,9838.96,13716.36,10285.10,
10326.76,6923.91,9246.01,7485.01,6390.07,7730.93,
7011.21,6626.57,6371.93,4041.32,3702.90,3434.10,
3813.69,4103.95,5320.81,8555.00,10854.10] * mult })
n = 14

def rsi_np():
# my numpy solution from above
return df

def rsi_loop():
# loop solution https://stackoverflow.com/a/57008625/3944322
# without the wrong alternative calculation of df['avg_gain'][14]
return df

df = df0.copy()
time_np = timeit.timeit('rsi_np()', globals=globals(), number = number) / 1000 * number

df = df0.copy()
time_loop = timeit.timeit('rsi_loop()', globals=globals(), number = number) / 1000 * number

print(f'rows\tnp\tloop\n{len(df0)}\t{time_np:.1f}\t{time_loop:.1f}')

assert np.allclose(rsi_np(), rsi_loop(), equal_nan=True)
``````

Results (ms / loop):

``````rows    np    loop
23      4.9   9.2
230     5.0   112.3
2300    5.5   1122.7
``````

So even for 8 rows (rows 15...22) the loop solution takes about twice the time of the numpy solution. Numpy scales well, whereas the loop solution isn't feasable for large datasets.

Here is an option.

I will be touching only on your second bullet

``````# libraries required
import pandas as pd
import numpy as np

# create dataframe
df = pd.DataFrame({'close':[4724.89, 4378.51,6463.00,9838.96,13716.36,10285.10,
10326.76,6923.91,9246.01,7485.01,6390.07,7730.93,
7011.21,6626.57,6371.93,4041.32,3702.90,3434.10,
3813.69,4103.95,5320.81,8555.00,10854.10]})

df['change'] = df['close'].diff(1) # Calculate change

# calculate gain / loss from every change
df['gain'] = np.select([df['change']>0, df['change'].isna()],
[df['change'], np.nan],
default=0)
df['loss'] = np.select([df['change']<0, df['change'].isna()],
[-df['change'], np.nan],
default=0)

# create avg_gain /  avg_loss columns with all nan
df['avg_gain'] = np.nan
df['avg_loss'] = np.nan

n = 14 # what is the window

# keep first occurrence of rolling mean
df['avg_gain'][n] = df['gain'].rolling(window=n).mean().dropna().iloc[0]
df['avg_loss'][n] = df['loss'].rolling(window=n).mean().dropna().iloc[0]
# Alternatively
df['avg_gain'][n] = df.loc[:n, 'gain'].mean()
df['avg_loss'][n] = df.loc[:n, 'loss'].mean()

# This is not a pandas way, looping through the pandas series, but it does what you need
for i in range(n+1, df.shape[0]):
df['avg_gain'].iloc[i] = (df['avg_gain'].iloc[i-1] * (n - 1) + df['gain'].iloc[i]) / n
df['avg_loss'].iloc[i] = (df['avg_loss'].iloc[i-1] * (n - 1) + df['loss'].iloc[i]) / n

# calculate rs and rsi
df['rs'] = df['avg_gain'] / df['avg_loss']
df['rsi'] = 100 - (100 / (1 + df['rs'] ))
``````
• I think this part: `df['avg_gain'][n] = df['gain'].rolling(window=n).mean().dropna().iloc[0] ` should be: `avg_gain[n] = gain[:n+1].mean()` Because for large DataFrame, rolling, mean and dropnan around DataFrame only to calculate 1 value is wasteful. But basically, your code works very well. Thanks Jul 12 '19 at 17:20
• `avg_gain[n] = gain[:n+1].mean()` is wrong, it must be avg_gain[n] = gain[:n].mean()`. Contrary to usual python slices, both the start and the stop are included in pandas slices, when present in the index
– Stef
Jul 15 '19 at 7:25

There is an easier way, the package talib.

``````import talib
close = df['close']
rsi = talib.RSI(close, timeperiod=14)
``````

If you'd like Bollinger Bands to go with your RSI that is easy too.

``````upperBB, middleBB, lowerBB = talib.BBANDS(close, timeperiod=20, nbdevup=2, nbdevdn=2, matype=0)
``````

You can use Bollinger Bands on RSI instead of the fixed reference levels of 70 and 30.

``````upperBBrsi, MiddleBBrsi, lowerBBrsi = talib.BBANDS(rsi, timeperiod=50, nbdevup=2, nbdevdn=2, matype=0)
``````

Finally, you can normalize RSI using the %b calcification.

``````normrsi = (rsi - lowerBBrsi) / (upperBBrsi - lowerBBrsi)
``````

info on talib https://mrjbq7.github.io/ta-lib/

info on Bollinger Bands https://www.BollingerBands.com

• The TA-lib does not give the corresponding values by tradingview Apr 10 '20 at 9:27
• @Justme talib's and TradingView's RSIs match perfectly for me. Perhaps there is a small difference in the two data sets you used to generate the indicator? What nobody has pointed out is that the answers here are incorrect as they do not use the unique smoothing method Welles Wilder specified for RSI. You can see the proper method in his book: amazon.com/New-Concepts-Technical-Trading-Systems/dp/0894590278
– John
Apr 11 '20 at 18:20
• Hi John, I runned a unittest and indeed tablib is giving corresponding values. The unittest is based on xls sheet from school.stockcharts.com/…. But then again comparing to tradingview I see different value (e.g. tradingview has 47,15 and talib gives 46,79). So is tradingview using Welles Wilders smoothing method? Apr 12 '20 at 10:48
• Cannot uno my - vote, only if you edit it with a dot i can undo the vote... Apr 12 '20 at 10:53
• @Justme It appears that the TV calc is incorrect. I find this hard to believe as I hold their platform in high regard. However, I have checked against three sources: AmiBroker, eSignal and TradeNavigator all of which agree. Perhaps I am missing something, in any case I will drop them a note.
– John
Apr 13 '20 at 15:28

ok guys here is Santa: this is the rsi code, replace every thing that has "aa":

``````import pandas as pd
rsi_period = 14
df = pd.Series(coinaalist)
chg = df.diff(1)