PandaPy
"I came across PandaPy last week and have already used it in my current project. It is a fascinating Python library with a lot of potential to become mainstream."
Snow, Derek (2020), PandaPy: A Wrapper Around Structured Arrays to Mimic ‘structs’ in the C Language, SSRN
@software{pandapy,
title = {{PandaPy}: A Wrapper Around Structured Arrays to Mimic ‘structs’ in the C Language.},
author = {Snow, Derek},
url = {https://github.com/firmai/pandapy/},
version = {1.11},
date = {2020-05-13},
}
Install
!pip3 install pandapy
Load
import pandapy as pp
Why PandaPy?
- Maintains the full functionality and speed of structured NumPy datatype (eg.,
array[col1] + array[col2], or np.log(array[col1]) - If you have smaller pandas dataframes (<50K number of records) in a production environment, then it is worth considering PandaPy, you will see a significant speed up and a large reduction in memory usage.
- When using mixed data types (int, float, datatime, str), PandaPy generally consumes (roughly a 1/3rd) less memory than Pandas.
- Pandas outperform PandaPy at the same point when Pandas outperform NumPy. NumPy generally performs better than pandas for 50K rows or less. Pandas generally performs better than numpy for 500K rows or more; from 50K to 500K rows it is a toss up depending on the operation.
- Because both Pandas and PandaPy is built on NumPy, the performance difference can be attributed to Pandas overhead. For larger datasets Pandas' hash tables and columnar data format gives it the upperhand on many operations.
- The performance claims therefore hold for small datasets, 1,000-100,000 numpy rows. There is however many PandaPy operations that improve relative to Pandas as the number of rows increase: rename, column drop, fillna mean, correlation matrix, filter (
array > 0), value reads(a=array[col]), singular value access (array[col][pos]), atomic functions (sqrt, power), and np. calculations differences even out (np.log, np.exp, etc). - Provides wrapper functions over NumPy to give you the usability of Pandas (eg.,
pp.group(array, [col1, col2, col2], ['mean', 'std'], ['Adj_Close','Close']) - If you need Pandas for speciality functions, you can easily
df = pp.pandas(array)and backarray = pp.structured(df) - For simple calculations on a small dataset (i.e, plus, mult, log) PandaPy is 25x - 80x faster than Pandas.
- For table functions (i.e., group, pivot, drop, concat, fillna) on a small data set PandaPy is 5x - 100x times faster than Pandas.
- For most use cases with small data, PandaPy is faster than Dask, Modin Ray and Pandas.
- The best competing python package for performance on table functions is datatable, it is 2x - 10x faster than PandaPy.
- The problem is that datatable is 5x - 10x slower with simple calculations (plus, mult, returns), it is less intuitive, does not have a large range of functions, have very few complementary libraries, e.g. matplotlib, and doesn't leave you in a Numpy datatype.
- For finance applications the speed of simple calculations takes preference over table function speed.
- PandaPy is not created to allow you to scale up to clusters for multiple computer processing like Dask, Modin, and Spark, instead it is focused on speed and usability within a single computer's Memory.
- Machines are getting large, EC2 X1 has 2TB of RAM and is remarkably affordable. If it can be done on a single machine then it should be done on a single machine. Quoting Dask - "For data that fits into RAM, Pandas {PandaPy, NumPy} can often be faster and easier to use than Dask DataFrame"
- If your dataset is very small you can load your data using PandaPy's
read()function, for medium sized data, it is best to load it with datatable or pyspark and convert it to structured Numpy, if it is large, pyspark, Dask, or Modin, if it is very large use pyspark. - Lastly PandaPy can have as input any multidimensional object and does not have to conform to the basic NumPy datatypes. It can include nested datatypes, subarrays, functions as long as each column conforms to the array lenght, this allows for a great amount of flexibility. You can for example,
add(array, "panda function",[[pd for i in range(len(multiple_stocks))]])to create a list of the panda (pd) module and access it along any index valuearray["panda function"][0].read_csv(url).
PandaPy software, similar to the original Pandas project, is developed to improve the usability of python for finance. Structured datatypes are designed to be able to mimic ‘structs’ in the C language, and share a similar memory layout. PandaPy currently houses more than 30 functions. Structured NumPy are meant for interfacing with C code and for low-level manipulation of structured buffers, for example for interpreting binary blobs. For these purposes they support specialized features such as subarrays, nested datatypes, and unions, and allow control over the memory layout of the structure.
Note this is a fledgling project, much room for improvement, all feedback appreciated (issues tab)
Description
A Structured NumPy Array is an array of structures. NumPy arrays can only contain one data type, but structured arrays in a sense create an array of homogeneous structures. This is done without moving out of NumPy such as is required with Xarray. For structured arrays the data type only has to be the same per column like an SQL data base. Each column can be another multidimensional object and does not have to conform to the basic NumPy datatypes.
PandaPy comes with similar functionality like Pandas, such as groupby, pivot, and others. The biggest benefit of this approach is that NumPy dtype(data type) directly maps onto a C structure definition, so the buffer containing the array content can be accessed directly within an appropriately written C program. If you find yourself writing a Python interface to a legacy C or Fortran library that manipulates structured data, you'll probably find structured arrays quite useful.
Additional
- Play around with speed tests here and some more here.
- Test and explore the package with this Google Colab Notebook.
- Get in touch on LinkedIn or Twitter.
- Use
table(array)to get a pandas looking table printout - You can read the paper on SSRN for a little more information.
Functions
PandaPy Speed Over Pandas In (X) e.g., (dropnarow) (30x)
Array Structure
Read In Arrays (read)
To Pandas (unstructured)
Pandas to Structured (structured)
To Unstructured (to_unstruct)
To Structured (to_struct)
Print Table (table)
Explorative Functions
Descriptive Statistics (describe) (5x)
Correlation Array (corr) (2x)
Finance Functions
Returns (returns) (50x)
Portfolio Value (portfolio_value) (50x)
Cummulative Value (cummulative_return) (50x)
Column Lags (lags) (7x)
Array Functions
Drop Null Rows (dropnarow) (30x)
Drop Column/s (drop) (100x)
Add Column/s (add) (3x)
Concatenate (concat) (rows 25x columns 70x)
Merge (merge) (2x)
Group by (group) (10x)
Pivot (pivot) (20x)
Fill Nulls (fillna) (20x)
Shift Column (shift) (50x)
Rename (rename) (500x)
Other Speed Tests
Update (array[col] = values) (60x)
Addition (array[col] + array[col]) (80x)
Multiplication (array[col] * array[col]) (80x)
Log (np.log(array[col]) (25x)
note speed tests done on financial dataset only
Documentation by Example
Read In Arrays
# First Example
multiple_stocks = pp.read('https://github.com/firmai/random-assets-two/blob/master/numpy/multiple_stocks.csv?raw=true')
closing = multiple_stocks[['Ticker','Date','Adj_Close']]
piv = pp.pivot(closing,"Date","Ticker","Adj_Close"); piv
closing = pp.to_struct(piv, name_list = [x for x in np.unique(multiple_stocks["Ticker"])])
# Second Example
tsla = pp.read('https://github.com/firmai/random-assets-two/raw/master/numpy/tsla.csv')
crm = pp.read('https://github.com/firmai/random-assets-two/raw/master/numpy/crm.csv')
tsla_sub = tsla[["Date","Adj_Close","Volume"]]
crm_sub = crm[["Date","Adj_Close","Volume"]]
crm_adj = crm[['Date','Adj_Close']]
closing
array([(37.24206924, 100.45429993, 44.57522202, 20.72605705, 130.59109497, 35.80251312, 41.9791832 , 81.51140594, 66.33999634),
(35.08446503, 97.62433624, 43.83200836, 20.34561157, 128.53627014, 35.80251312, 41.59314346, 80.89860535, 66.15000153),
(35.34244537, 97.63354492, 42.79874039, 19.90727234, 125.76422119, 36.07437897, 40.98268127, 80.28580475, 64.58000183),
...,
(21.57999992, 289.79998779, 59.08000183, 11.18000031, 135.27000427, 55.34999847, 158.96000671, 137.53999329, 88.37000275),
(21.34000015, 291.51998901, 58.65999985, 11.07999992, 132.80999756, 55.27000046, 157.58999634, 136.80999756, 87.95999908),
(21.51000023, 293.6499939 , 58.47999954, 11.15999985, 134.03999329, 55.34999847, 157.69999695, 136.66999817, 88.08999634)],
dtype=[('AA', '
Rename
pp.rename(closing,["AA","AAPL"],["GAP","FAF"])[:5]
array([(37.24206924, 100.45429993, 44.57522202, 20.72605705, 130.59109497, 35.80251312, 41.9791832 , 81.51140594, 66.33999634),
(35.08446503, 97.62433624, 43.83200836, 20.34561157, 128.53627014, 35.80251312, 41.59314346, 80.89860535, 66.15000153),
(35.34244537, 97.63354492, 42.79874039, 19.90727234, 125.76422119, 36.07437897, 40.98268127, 80.28580475, 64.58000183),
(36.25707626, 99.00255585, 42.57216263, 19.91554451, 124.94229126, 36.52467346, 41.50337982, 82.63342285, 65.52999878),
(37.28897095, 102.80648041, 43.67792892, 20.15538216, 127.65791321, 36.966465 , 42.72432327, 84.13523865, 66.63999939)],
dtype=[('GAP', '
pp.rename(closing,"AA", "GALLY")[:5]
array([(37.24206924, 100.45429993, 44.57522202, 20.72605705, 130.59109497, 35.80251312, 41.9791832 , 81.51140594, 66.33999634),
(35.08446503, 97.62433624, 43.83200836, 20.34561157, 128.53627014, 35.80251312, 41.59314346, 80.89860535, 66.15000153),
(35.34244537, 97.63354492, 42.79874039, 19.90727234, 125.76422119, 36.07437897, 40.98268127, 80.28580475, 64.58000183),
(36.25707626, 99.00255585, 42.57216263, 19.91554451, 124.94229126, 36.52467346, 41.50337982, 82.63342285, 65.52999878),
(37.28897095, 102.80648041, 43.67792892, 20.15538216, 127.65791321, 36.966465 , 42.72432327, 84.13523865, 66.63999939)],
dtype=[('GALLY', '
Statistics
described = pp.describe(closing)
Describe
observations
minimum
maximum
mean
variance
skewness
kurtosis
AA
1258.00
15.97
60.23
31.46
99.42
0.67
-0.58
AAPL
1258.00
85.39
293.65
149.45
2119.86
0.66
-0.28
DAL
1258.00
30.73
62.69
47.15
44.33
-0.01
-0.78
GE
1258.00
6.42
28.67
18.85
48.45
-0.25
-1.54
IBM
1258.00
99.83
161.17
133.35
116.28
-0.37
0.56
KO
1258.00
32.81
55.35
41.67
28.86
0.80
-0.05
MSFT
1258.00
36.27
158.96
78.31
1102.21
0.61
-0.82
PEP
1258.00
78.46
139.30
102.86
229.01
0.63
-0.32
UAL
1258.00
37.75
96.70
69.22
195.65
0.02
-1.04
Drop Column/s
removed = pp.drop(closing,["AA","AAPL","IBM"]) ; removed[:5]
array([(44.57522202, 20.72605705, 35.80251312, 41.9791832 , 81.51140594, 66.33999634),
(43.83200836, 20.34561157, 35.80251312, 41.59314346, 80.89860535, 66.15000153),
(42.79874039, 19.90727234, 36.07437897, 40.98268127, 80.28580475, 64.58000183),
(42.57216263, 19.91554451, 36.52467346, 41.50337982, 82.63342285, 65.52999878),
(43.67792892, 20.15538216, 36.966465 , 42.72432327, 84.13523865, 66.63999939)],
dtype={'names':['DAL','GE','KO','MSFT','PEP','UAL'], 'formats':['
Add Column/s
added = pp.add(closing,["GALLY","FAF"],[closing["IBM"],closing["AA"]]); added[:5] ## set two new columns with that two previous columnns
array([(37.24206924, 100.45429993, 44.57522202, 20.72605705, 130.59109497, 35.80251312, 41.9791832 , 81.51140594, 66.33999634, 130.59109497, 37.24206924),
(35.08446503, 97.62433624, 43.83200836, 20.34561157, 128.53627014, 35.80251312, 41.59314346, 80.89860535, 66.15000153, 128.53627014, 35.08446503),
(35.34244537, 97.63354492, 42.79874039, 19.90727234, 125.76422119, 36.07437897, 40.98268127, 80.28580475, 64.58000183, 125.76422119, 35.34244537),
(36.25707626, 99.00255585, 42.57216263, 19.91554451, 124.94229126, 36.52467346, 41.50337982, 82.63342285, 65.52999878, 124.94229126, 36.25707626),
(37.28897095, 102.80648041, 43.67792892, 20.15538216, 127.65791321, 36.966465 , 42.72432327, 84.13523865, 66.63999939, 127.65791321, 37.28897095)],
dtype=[('AA', '
Concatenate Arrays by Row
concat_row = pp.concat(removed[["DAL","GE"]], added[["PEP","UAL"]], type="row"); concat_row[:5]
array([(44.57522202, 20.72605705), (43.83200836, 20.34561157),
(42.79874039, 19.90727234), (42.57216263, 19.91554451),
(43.67792892, 20.15538216)], dtype=[('DAL', '
Concatenate Arrays by Column
concat_col = pp.concat(removed[["DAL","GE"]], added[["PEP","UAL"]], type="columns"); concat_col[:5]
array([(44.57522202, 20.72605705, 81.51140594, 66.33999634),
(43.83200836, 20.34561157, 80.89860535, 66.15000153),
(42.79874039, 19.90727234, 80.28580475, 64.58000183),
(42.57216263, 19.91554451, 82.63342285, 65.52999878),
(43.67792892, 20.15538216, 84.13523865, 66.63999939)],
dtype=[('DAL', '
Concatenate by Array
concat_array = pp.concat(removed[["DAL","GE"]], added[["PEP","UAL"]], type="array"); concat_array[:5]
array([[(44.57522201538086, 20.726057052612305),
(43.832008361816406, 20.345611572265625),
(42.79874038696289, 19.907272338867188), ...,
(59.08000183105469, 11.180000305175781),
(58.65999984741211, 11.079999923706055),
(58.47999954223633, 11.15999984741211)],
[(81.51140594482422, 66.33999633789062),
(80.89860534667969, 66.1500015258789),
(80.28580474853516, 64.58000183105469), ...,
(137.5399932861328, 88.37000274658203),
(136.80999755859375, 87.95999908447266),
(136.6699981689453, 88.08999633789062)]], dtype=object)
Concatenate by Melt
concat_melt = pp.concat(removed[["DAL","GE"]], added[["PEP","UAL"]], type="melt"); concat_melt[:5]
array([(44.57522202, 20.72605705), (43.83200836, 20.34561157),
(42.79874039, 19.90727234), (42.57216263, 19.91554451),
(43.67792892, 20.15538216)], dtype=[('DAL', '
Merge Array (inner, outer)
merged = pp.merge(tsla_sub, crm_adj, left_on="Date", right_on="Date",how="inner",left_postscript="_TSLA",right_postscript="_CRM"); merged[:5]
array([('2019-01-02', 310.11999512, 135.55000305, 11658600),
('2019-01-03', 300.35998535, 130.3999939 , 6965200),
('2019-01-04', 317.69000244, 137.96000671, 7394100),
('2019-01-07', 334.95999146, 142.22000122, 7551200),
('2019-01-08', 335.3500061 , 145.72000122, 7008500)],
dtype=[('Date', '
Replace Individual Values
## More work to done on replace (structured)
## replace(merged,original=317.69000244, replacement=np.nan)[:5]
Print Table
pp.table(merged[:5])
Date
Adj_Close_TSLA
Adj_Close_CRM
Volume
0
2019-01-02
310.120
135.550
11658600
1
2019-01-03
300.360
130.400
6965200
2
2019-01-04
317.690
137.960
7394100
3
2019-01-07
334.960
142.220
7551200
4
2019-01-08
335.350
145.720
7008500
### This is the new function that you should include above
### You can add the same peculuarities to remove
Add and Concatenate
tsla = pp.add(tsla,["Ticker"], "TSLA", "U10")
crm = pp.add(crm,["Ticker"], "CRM", "U10")
combine = pp.concat(tsla[0:5], crm[0:5], type="row"); combine
array([(315.13000488, 298.79998779, 306.1000061 , 310.11999512, 11658600, 310.11999512, '2019-01-02', 'TSLA'),
(309.3999939 , 297.38000488, 307. , 300.35998535, 6965200, 300.35998535, '2019-01-03', 'TSLA'),
(318. , 302.73001099, 306. , 317.69000244, 7394100, 317.69000244, '2019-01-04', 'TSLA'),
(336.73999023, 317.75 , 321.72000122, 334.95999146, 7551200, 334.95999146, '2019-01-07', 'TSLA'),
(344.01000977, 327.01998901, 341.95999146, 335.3500061 , 7008500, 335.3500061 , '2019-01-08', 'TSLA'),
(136.83000183, 133.05000305, 133.3999939 , 135.55000305, 4783900, 135.55000305, '2019-01-02', 'CRM'),
(134.77999878, 130.1000061 , 133.47999573, 130.3999939 , 6365700, 130.3999939 , '2019-01-03', 'CRM'),
(139.32000732, 132.22000122, 133.5 , 137.96000671, 6650600, 137.96000671, '2019-01-04', 'CRM'),
(143.38999939, 138.78999329, 141.02000427, 142.22000122, 9064800, 142.22000122, '2019-01-07', 'CRM'),
(146.46000671, 142.88999939, 144.72999573, 145.72000122, 9057300, 145.72000122, '2019-01-08', 'CRM')],
dtype=[('High', '
dropped = pp.drop(combine,["High","Low","Open"]); dropped[:10]
array([(310.11999512, 11658600, 310.11999512, '2019-01-02', 'TSLA'),
(300.35998535, 6965200, 300.35998535, '2019-01-03', 'TSLA'),
(317.69000244, 7394100, 317.69000244, '2019-01-04', 'TSLA'),
(334.95999146, 7551200, 334.95999146, '2019-01-07', 'TSLA'),
(335.3500061 , 7008500, 335.3500061 , '2019-01-08', 'TSLA'),
(135.55000305, 4783900, 135.55000305, '2019-01-02', 'CRM'),
(130.3999939 , 6365700, 130.3999939 , '2019-01-03', 'CRM'),
(137.96000671, 6650600, 137.96000671, '2019-01-04', 'CRM'),
(142.22000122, 9064800, 142.22000122, '2019-01-07', 'CRM'),
(145.72000122, 9057300, 145.72000122, '2019-01-08', 'CRM')],
dtype={'names':['Close','Volume','Adj_Close','Date','Ticker'], 'formats':['
Pivot Array
piv = pp.pivot(dropped,"Date","Ticker","Adj_Close",display=True)
Adj_Close
CRM
TSLA
2019-01-02
135.55
310.12
2019-01-03
130.40
300.36
2019-01-04
137.96
317.69
2019-01-07
142.22
334.96
2019-01-08
145.72
335.35
Add New Data types
tsla_extended = pp.add(tsla,"Month",tsla["Date"],'datetime64[M]')
tsla_extended = pp.add(tsla_extended,"Year",tsla_extended["Date"],'datetime64[Y]')
Update Existing Column
## faster method elsewhere
year_frame = pp.update(tsla,"Date", [dt.year for dt in tsla["Date"].astype(object)],types="|U10"); year_frame[:5]
array([(315.13000488, 298.79998779, 306.1000061 , 310.11999512, 11658600, 310.11999512, 'TSLA', '2019'),
(309.3999939 , 297.38000488, 307. , 300.35998535, 6965200, 300.35998535, 'TSLA', '2019'),
(318. , 302.73001099, 306. , 317.69000244, 7394100, 317.69000244, 'TSLA', '2019'),
(336.73999023, 317.75 , 321.72000122, 334.95999146, 7551200, 334.95999146, 'TSLA', '2019'),
(344.01000977, 327.01998901, 341.95999146, 335.3500061 , 7008500, 335.3500061 , 'TSLA', '2019')],
dtype=[('High', '
Group Arrays By
grouped = pp.group(tsla_extended, ['Ticker','Month','Year'],['mean', 'std', 'min', 'max'], ['Adj_Close','Close'], display=True)
Ticker
Month
Year
Adj_Close_mean
Adj_Close_std
Adj_Close_min
Adj_Close_max
Close_mean
Close_std
Close_min
Close_max
0
TSLA
2019-01-01
2019-01-01
318.494
21.098
287.590
347.310
318.494
21.098
287.590
347.310
1
TSLA
2019-02-01
2019-01-01
307.728
8.053
291.230
321.350
307.728
8.053
291.230
321.350
2
TSLA
2019-03-01
2019-01-01
277.757
8.925
260.420
294.790
277.757
8.925
260.420
294.790
3
TSLA
2019-04-01
2019-01-01
266.656
14.985
235.140
291.810
266.656
14.985
235.140
291.810
4
TSLA
2019-05-01
2019-01-01
219.715
24.040
185.160
255.340
219.715
24.040
185.160
255.340
5
TSLA
2019-06-01
2019-01-01
213.717
12.125
178.970
226.430
213.717
12.125
178.970
226.430
6
TSLA
2019-07-01
2019-01-01
242.382
12.077
224.550
264.880
242.382
12.077
224.550
264.880
7
TSLA
2019-08-01
2019-01-01
225.103
7.831
211.400
238.300
225.103
7.831
211.400
238.300
8
TSLA
2019-09-01
2019-01-01
237.261
8.436
220.680
247.100
237.261
8.436
220.680
247.100
9
TSLA
2019-10-01
2019-01-01
266.355
31.463
231.430
328.130
266.355
31.463
231.430
328.130
10
TSLA
2019-11-01
2019-01-01
338.300
13.226
313.310
359.520
338.300
13.226
313.310
359.520
11
TSLA
2019-12-01
2019-01-01
377.695
36.183
330.370
430.940
377.695
36.183
330.370
430.940
Convert Array to Pandas
grouped_frame = pp.pandas(grouped); grouped_frame.head()
Ticker
Month
Year
Adj_Close_mean
Adj_Close_std
Adj_Close_min
Adj_Close_max
Close_mean
Close_std
Close_min
Close_max
0
TSLA
2019-01-01
2019-01-01
318.494284
21.098362
287.589996
347.309998
318.494284
21.098362
287.589996
347.309998
1
TSLA
2019-02-01
2019-01-01
307.728421
8.052522
291.230011
321.350006
307.728421
8.052522
291.230011
321.350006
2
TSLA
2019-03-01
2019-01-01
277.757140
8.924873
260.420013
294.790009
277.757140
8.924873
260.420013
294.790009
3
TSLA
2019-04-01
2019-01-01
266.655716
14.984572
235.139999
291.809998
266.655716
14.984572
235.139999
291.809998
4
TSLA
2019-05-01
2019-01-01
219.715454
24.039647
185.160004
255.339996
219.715454
24.039647
185.160004
255.339996
From Pandas to Structured
struct = pp.structured(grouped_frame); struct[:5]
rec.array([('TSLA', '2019-01-01T00:00:00.000000000', '2019-01-01T00:00:00.000000000', 318.49428449, 21.09836186, 287.58999634, 347.30999756, 318.49428449, 21.09836186, 287.58999634, 347.30999756),
('TSLA', '2019-02-01T00:00:00.000000000', '2019-01-01T00:00:00.000000000', 307.72842086, 8.05252198, 291.23001099, 321.3500061 , 307.72842086, 8.05252198, 291.23001099, 321.3500061 ),
('TSLA', '2019-03-01T00:00:00.000000000', '2019-01-01T00:00:00.000000000', 277.75713966, 8.92487345, 260.42001343, 294.79000854, 277.75713966, 8.92487345, 260.42001343, 294.79000854),
('TSLA', '2019-04-01T00:00:00.000000000', '2019-01-01T00:00:00.000000000', 266.65571594, 14.98457194, 235.13999939, 291.80999756, 266.65571594, 14.98457194, 235.13999939, 291.80999756),
('TSLA', '2019-05-01T00:00:00.000000000', '2019-01-01T00:00:00.000000000', 219.7154541 , 24.03964724, 185.16000366, 255.33999634, 219.7154541 , 24.03964724, 185.16000366, 255.33999634)],
dtype=[('Ticker', 'O'), ('Month', '
Shift Column
pp.shift(merged["Adj_Close_TSLA"],1)[:5]
array([ nan, 310.11999512, 300.35998535, 317.69000244,
334.95999146])
Multiple Lags for Column
tsla_lagged = pp.lags(tsla_extended, "Adj_Close", 5); tsla_lagged[:5]
array([(315.13000488, 298.79998779, 306.1000061 , 310.11999512, 11658600, 310.11999512, '2019-01-02', 'TSLA', '2019-01', '2019', nan, nan, nan, nan, nan),
(309.3999939 , 297.38000488, 307. , 300.35998535, 6965200, 300.35998535, '2019-01-03', 'TSLA', '2019-01', '2019', 310.11999512, nan, nan, nan, nan),
(318. , 302.73001099, 306. , 317.69000244, 7394100, 317.69000244, '2019-01-04', 'TSLA', '2019-01', '2019', 300.35998535, 310.11999512, nan, nan, nan),
(336.73999023, 317.75 , 321.72000122, 334.95999146, 7551200, 334.95999146, '2019-01-07', 'TSLA', '2019-01', '2019', 317.69000244, 300.35998535, 310.11999512, nan, nan),
(344.01000977, 327.01998901, 341.95999146, 335.3500061 , 7008500, 335.3500061 , '2019-01-08', 'TSLA', '2019-01', '2019', 334.95999146, 317.69000244, 300.35998535, 310.11999512, nan)],
dtype=[('High', '
Correlation Array
correlated = pp.corr(closing)
Correlation
AA
AAPL
DAL
GE
IBM
KO
MSFT
PEP
UAL
AA
1.00
0.21
0.24
-0.17
0.39
-0.09
0.05
-0.04
0.12
AAPL
0.21
1.00
0.86
-0.83
0.22
0.85
0.94
0.85
0.82
DAL
0.24
0.86
1.00
-0.78
0.14
0.79
0.86
0.78
0.86
GE
-0.17
-0.83
-0.78
1.00
0.06
-0.76
-0.86
-0.69
-0.76
IBM
0.39
0.22
0.14
0.06
1.00
0.07
0.15
0.24
0.18
KO
-0.09
0.85
0.79
-0.76
0.07
1.00
0.94
0.96
0.74
MSFT
0.05
0.94
0.86
-0.86
0.15
0.94
1.00
0.93
0.83
PEP
-0.04
0.85
0.78
-0.69
0.24
0.96
0.93
1.00
0.75
UAL
0.12
0.82
0.86
-0.76
0.18
0.74
0.83
0.75
1.00
Log Returns
pp.returns(closing,"IBM",type="log")
array([ nan, -0.01585991, -0.02180223, ..., 0.0026649 ,
-0.0183533 , 0.0092187 ])
Normal Returns
loga = pp.returns(closing,"IBM",type="normal"); loga
array([ nan, -0.0157348 , -0.02156628, ..., 0.00266845,
-0.0181859 , 0.00926132])
Add Column
close_ret = pp.add(closing,"IBM_log_return",loga); close_ret[:5]
array([(37.24206924, 100.45429993, 44.57522202, 20.72605705, 130.59109497, 35.80251312, 41.9791832 , 81.51140594, 66.33999634, nan),
(35.08446503, 97.62433624, 43.83200836, 20.34561157, 128.53627014, 35.80251312, 41.59314346, 80.89860535, 66.15000153, -0.0157348 ),
(35.34244537, 97.63354492, 42.79874039, 19.90727234, 125.76422119, 36.07437897, 40.98268127, 80.28580475, 64.58000183, -0.02156628),
(36.25707626, 99.00255585, 42.57216263, 19.91554451, 124.94229126, 36.52467346, 41.50337982, 82.63342285, 65.52999878, -0.00653548),
(37.28897095, 102.80648041, 43.67792892, 20.15538216, 127.65791321, 36.966465 , 42.72432327, 84.13523865, 66.63999939, 0.02173501)],
dtype=[('AA', '
Drop Array Rows Where Null
close_ret_na = pp.dropnarow(close_ret, "IBM_log_return"); close_ret[:5]
array([(37.24206924, 100.45429993, 44.57522202, 20.72605705, 130.59109497, 35.80251312, 41.9791832 , 81.51140594, 66.33999634, nan),
(35.08446503, 97.62433624, 43.83200836, 20.34561157, 128.53627014, 35.80251312, 41.59314346, 80.89860535, 66.15000153, -0.0157348 ),
(35.34244537, 97.63354492, 42.79874039, 19.90727234, 125.76422119, 36.07437897, 40.98268127, 80.28580475, 64.58000183, -0.02156628),
(36.25707626, 99.00255585, 42.57216263, 19.91554451, 124.94229126, 36.52467346, 41.50337982, 82.63342285, 65.52999878, -0.00653548),
(37.28897095, 102.80648041, 43.67792892, 20.15538216, 127.65791321, 36.966465 , 42.72432327, 84.13523865, 66.63999939, 0.02173501)],
dtype=[('AA', '
Portfolio Value from Log Return
pp.portfolio_value(close_ret_na, "IBM_log_return", type="log")
array([0.98438834, 0.96338604, 0.95711037, ..., 1.15115429, 1.13040872,
1.14092643])
Cummulative Value from Log Return
pp.cummulative_return(close_ret_na, "IBM_log_return", type="log")
array([-0.01561166, -0.03661396, -0.04288963, ..., 0.15115429,
0.13040872, 0.14092643])
Fillna Mean
pp.fillna(tsla_lagged,type="mean")[:5]
array([(315.13000488, 298.79998779, 306.1000061 , 310.11999512, 11658600, 310.11999512, 272.95330665, 272.38631982, 271.75180703, 271.10991915, 270.48587024),
(309.3999939 , 297.38000488, 307. , 300.35998535, 6965200, 300.35998535, 310.11999512, 272.38631982, 271.75180703, 271.10991915, 270.48587024),
(318. , 302.73001099, 306. , 317.69000244, 7394100, 317.69000244, 300.35998535, 310.11999512, 271.75180703, 271.10991915, 270.48587024),
(336.73999023, 317.75 , 321.72000122, 334.95999146, 7551200, 334.95999146, 317.69000244, 300.35998535, 310.11999512, 271.10991915, 270.48587024),
(344.01000977, 327.01998901, 341.95999146, 335.3500061 , 7008500, 335.3500061 , 334.95999146, 317.69000244, 300.35998535, 310.11999512, 270.48587024)],
dtype={'names':['High','Low','Open','Close','Volume','Adj_Close','Adj_Close_lag_1','Adj_Close_lag_2','Adj_Close_lag_3','Adj_Close_lag_4','Adj_Close_lag_5'], 'formats':['
Fillna Value
pp.fillna(tsla_lagged,type="value",value=-999999)[:5]
array([(315.13000488, 298.79998779, 306.1000061 , 310.11999512, 11658600, 310.11999512, -9.99999000e+05, -9.99999000e+05, -9.99999000e+05, -9.99999000e+05, -999999.),
(309.3999939 , 297.38000488, 307. , 300.35998535, 6965200, 300.35998535, 3.10119995e+02, -9.99999000e+05, -9.99999000e+05, -9.99999000e+05, -999999.),
(318. , 302.73001099, 306. , 317.69000244, 7394100, 317.69000244, 3.00359985e+02, 3.10119995e+02, -9.99999000e+05, -9.99999000e+05, -999999.),
(336.73999023, 317.75 , 321.72000122, 334.95999146, 7551200, 334.95999146, 3.17690002e+02, 3.00359985e+02, 3.10119995e+02, -9.99999000e+05, -999999.),
(344.01000977, 327.01998901, 341.95999146, 335.3500061 , 7008500, 335.3500061 , 3.34959991e+02, 3.17690002e+02, 3.00359985e+02, 3.10119995e+02, -999999.)],
dtype={'names':['High','Low','Open','Close','Volume','Adj_Close','Adj_Close_lag_1','Adj_Close_lag_2','Adj_Close_lag_3','Adj_Close_lag_4','Adj_Close_lag_5'], 'formats':['
Fillna Forward Fill
pp.fillna(tsla_lagged,type="ffill")[:5]
array([(315.13000488, 298.79998779, 306.1000061 , 310.11999512, 11658600, 310.11999512, nan, nan, nan, nan, nan),
(309.3999939 , 297.38000488, 307. , 300.35998535, 6965200, 300.35998535, 310.11999512, nan, nan, nan, nan),
(318. , 302.73001099, 306. , 317.69000244, 7394100, 317.69000244, 300.35998535, 310.11999512, nan, nan, nan),
(336.73999023, 317.75 , 321.72000122, 334.95999146, 7551200, 334.95999146, 317.69000244, 300.35998535, 310.11999512, nan, nan),
(344.01000977, 327.01998901, 341.95999146, 335.3500061 , 7008500, 335.3500061 , 334.95999146, 317.69000244, 300.35998535, 310.11999512, nan)],
dtype={'names':['High','Low','Open','Close','Volume','Adj_Close','Adj_Close_lag_1','Adj_Close_lag_2','Adj_Close_lag_3','Adj_Close_lag_4','Adj_Close_lag_5'], 'formats':['
Fillna Backward Fill
pp.fillna(tsla_lagged,type="bfill")[:5]
array([(315.13000488, 298.79998779, 306.1000061 , 310.11999512, 11658600, 310.11999512, 310.11999512, 310.11999512, 310.11999512, 310.11999512, 310.11999512),
(309.3999939 , 297.38000488, 307. , 300.35998535, 6965200, 300.35998535, 310.11999512, 310.11999512, 310.11999512, 310.11999512, 310.11999512),
(318. , 302.73001099, 306. , 317.69000244, 7394100, 317.69000244, 300.35998535, 310.11999512, 310.11999512, 310.11999512, 310.11999512),
(336.73999023, 317.75 , 321.72000122, 334.95999146, 7551200, 334.95999146, 317.69000244, 300.35998535, 310.11999512, 310.11999512, 310.11999512),
(344.01000977, 327.01998901, 341.95999146, 335.3500061 , 7008500, 335.3500061 , 334.95999146, 317.69000244, 300.35998535, 310.11999512, 310.11999512)],
dtype={'names':['High','Low','Open','Close','Volume','Adj_Close','Adj_Close_lag_1','Adj_Close_lag_2','Adj_Close_lag_3','Adj_Close_lag_4','Adj_Close_lag_5'], 'formats':['
Print Table
pp.table(tsla_lagged,5)
High
Low
Open
Close
Volume
Adj_Close
Date
Ticker
Month
Year
Adj_Close_lag_1
Adj_Close_lag_2
Adj_Close_lag_3
Adj_Close_lag_4
Adj_Close_lag_5
0
315.130
298.800
306.100
310.120
11658600
310.120
2019-01-02
TSLA
2019-01-01
2019-01-01
nan
nan
nan
nan
nan
1
309.400
297.380
307.000
300.360
6965200
300.360
2019-01-03
TSLA
2019-01-01
2019-01-01
310.120
nan
nan
nan
nan
2
318.000
302.730
306.000
317.690
7394100
317.690
2019-01-04
TSLA
2019-01-01
2019-01-01
300.360
310.120
nan
nan
nan
3
336.740
317.750
321.720
334.960
7551200
334.960
2019-01-07
TSLA
2019-01-01
2019-01-01
317.690
300.360
310.120
nan
nan
4
344.010
327.020
341.960
335.350
7008500
335.350
2019-01-08
TSLA
2019-01-01
2019-01-01
334.960
317.690
300.360
310.120
nan
Outliers
signal = tsla_lagged["Volume"]
z_signal = (signal - np.mean(signal)) / np.std(signal)
tsla_lagged = pp.add(tsla_lagged,"z_signal_volume",z_signal)
outliers = pp.detect(tsla_lagged["z_signal_volume"]); outliers
[12, 40, 42, 64, 78, 79, 84, 95, 97, 98, 107, 141, 205, 206, 207]
import matplotlib.pyplot as plt
plt.figure(figsize=(15, 7))
plt.plot(np.arange(len(tsla_lagged["Volume"])), tsla_lagged["Volume"])
plt.plot(np.arange(len(tsla_lagged["Volume"])), tsla_lagged["Volume"], 'X', label='outliers',markevery=outliers, c='r')
plt.legend()
plt.show()
Remove Noise
price_signal = tsla_lagged["Close"]
removed_signal = pp.removal(price_signal, 30)
noise = pp.get(price_signal, removed_signal)
plt.figure(figsize=(15, 7))
plt.subplot(2, 1, 1)
plt.plot(removed_signal)
plt.title('timeseries without noise')
plt.subplot(2, 1, 2)
plt.plot(noise)
plt.title('noise timeseries')
plt.show()
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